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. 2011 Jul 8;23(7):2725–2737. doi: 10.1105/tpc.111.088088

The FRD3 Citrate Effluxer Promotes Iron Nutrition between Symplastically Disconnected Tissues throughout Arabidopsis Development[C],[W]

Hannetz Roschzttardtz 1,1,2, Mathilde Séguéla-Arnaud 1,1,3, Jean-François Briat 1, Grégory Vert 1, Catherine Curie 1,4
PMCID: PMC3226209  PMID: 21742986

This work examines the role of the citrate transporter FRD3 in iron homeostasis during plant development, finding key roles in pollen and embryo development, and in leaf, in addition to its known role in roots and in the apoplastic transport of iron.

Abstract

We present data supporting a general role for FERRIC REDICTASE DEFECTIVE3 (FRD3), an efflux transporter of the efficient iron chelator citrate, in maintaining iron homeostasis throughout plant development. In addition to its well-known expression in root, we show that FRD3 is strongly expressed in Arabidopsis thaliana seed and flower. Consistently, frd3 loss-of-function mutants are defective in early germination and are almost completely sterile, both defects being rescued by iron and/or citrate supply. The frd3 fertility defect is caused by pollen abortion and is associated with the male gametophytic expression of FRD3. Iron imaging shows the presence of important deposits of iron on the surface of aborted pollen grains. This points to a role for FRD3 and citrate in proper iron nutrition of embryo and pollen. Based on the findings that iron acquisition in embryo, leaf, and pollen depends on FRD3, we propose that FRD3 mediated-citrate release in the apoplastic space represents an important process by which efficient iron nutrition is achieved between adjacent tissues lacking symplastic connections. These results reveal a physiological role for citrate in the apoplastic transport of iron throughout development, and provide a general model for multicellular organisms in the cell-to-cell transport of iron involving extracellular circulation.

INTRODUCTION

Iron is essential for a plethora of cellular functions. In plants, its availability is known to affect developmental programs such as root morphogenesis (Schmidt, 1999) and flower development and color (Takahashi et al., 2003; Momonoi et al., 2009). Iron entry in the biosphere is often limited by its solubility in the soil, despite its great abundance. In particular, Fe3+ ions precipitate in alkaline soils, thereby preventing their extraction by plant roots. Symptoms of iron shortage in plants include chlorosis and poor growth due to the impairment of numerous metabolic pathways that require iron-containing proteins. To cope with iron deficiency, plants have developed physiological and molecular strategies that increase iron mobilization in the rhizosphere and enable high-affinity iron uptake. In Arabidopsis thaliana, these include (1) a modification of the root architecture to increase foraging capacity, (2) the acidification of the root vicinity by rhizodermic cells through the proton ATPase AHA2 (Santi and Schmidt, 2009) and to the extrusion of organic acids, (3) the reduction of Fe3+ in Fe2+ by a ferric-chelate reductase encoded by the FERRIC REDUCTASE OXIDASE2 (FRO2) gene (Robinson et al., 1999), and (4) the uptake of Fe2+ by the metal transporter IRON REGULATED TRANSPORTER1 (IRT1) (Eide et al., 1996; Henriques et al., 2002; Varotto et al., 2002; Vert et al., 2002). As IRT1 displays a broad selectivity for metal ions (Eide et al., 1996), it is also responsible for the perverse entry of heavy metals in iron-starved plants (Vert et al., 2002). Expression of the IRT1 and FRO2 genes, which occurs specifically in root epidermal cells of iron-deficient plants, is mostly controlled at the transcriptional level (Connolly et al., 2002; Vert et al., 2002, 2003) and involves the basic HELIX LOOP HELIX transcription factor Fe-DEFICIENCY INDUCED FACTOR1, itself upregulated by iron deficiency (Colangelo and Guerinot, 2004; Jakoby et al., 2004; Yuan et al., 2005).

Because free ionic iron can cause cell damage by catalyzing the production of highly toxic reactive oxygen species, iron is always found bound to its target metalloproteins or chelated to organic or mineral ligands. Citrate is likely an important ligand of iron in animals and plants, in particular, in the extracellular fluids. In the brain interstitium where citrate is released in large amount by astrocytes, part of the nontransferrin-bound iron pool that circulates might be complexed with citrate because neurons have been shown to take up Fe-citrate (reviewed in Moos et al., 2007). In the xylem sap of many plant species, iron has been thought to circulate as Fe-citrate. Citrate concentration is indeed markedly increased by iron starvation in xylem exudates (Brown, 1966; López-Millán et al., 2000), and the acidic pH of this apoplastic fluid is compatible with the stability of the Fe-citrate complex. Only recently, however, has the presence of Fe-citrate complexes, in the form of tri-Fe(III) tri-citrate and di-Fe(III) di-citrate, been detected in xylem exudates of tomato plants (Rellán-Alvarez et al., 2010).

Multidrug and toxic compound extrusion (MATE) transporters are involved in the efflux of xenobiotics and metabolites from cells in prokaryotes and eukaryotes (reviewed in Omote et al., 2006). The number of MATE-type transporters is very large in plants compared with bacteria and animals. The Arabidopsis genome encodes 58 MATE transporters, which suggests that plants can efflux a large number of metabolites (Yazaki, 2005). Thus far, only a few plant MATEs have been functionally characterized. A number of MATEs transport endogenous molecules, such as pigments, in the vacuole. Arabidopsis TRANSPARENT TESTA 12 and Medicago truncatula MATE1 transport precursors for proanthocyanidin biosynthesis in the vacuole of seed coat cells (Debeaujon et al., 2001; Marinova et al., 2007; Zhao and Dixon, 2009), whereas in grapevine berries, AnthoMATE1 and AnthoMATE3 likely transport acylated anthocyanins in the vacuole (Gomez et al., 2009). Other MATE members detoxify endogenous molecules, xenobiotics, and toxic elements by efflux into the apoplastic space. Arabidopsis thaliana detoxification1 was shown to mediate efflux of plant-derived alkaloids, antibiotics, and Cd2+ (Li et al., 2002). Moreover, as shown in many plant species, aluminum tolerance is conferred by MATE-mediated citrate efflux in the rhizosphere (Li et al., 2002; Furukawa et al., 2007; Liu et al., 2009; Maron et al., 2010).

Arabidopsis FERRIC REDICTASE DEFECTIVE3 (FRD3) and its ortholog in rice (Oryza sativa), Os FRDL1, are plasma membrane citrate efflux transporters and represent important components of the iron homeostasis machinery (Rogers and Guerinot, 2002; Green and Rogers, 2004; Durrett et al., 2007; Yokosho et al., 2009). The first mutant allele of FRD3 was isolated as a manganese accumulator plant of Arabidopsis, hence was designated man1 (Delhaize, 1996). man1 was described as a chlorotic and dwarf mutant that contains an increased concentration of iron in the root and displays a constitutive root ferric-chelate reductase activity (Delhaize, 1996). Two additional alleles, frd3-1 and frd3-2, were isolated in a screen for Arabidopsis ethyl methanesulfonate (EMS)-mutagenized mutants with constitutive root ferric-chelate reductase activity (Rogers and Guerinot, 2002). In Arabidopsis frd3 and rice frdl1 knockout mutants, the expression of iron deficiency-induced genes is high regardless of the iron status (Rogers and Guerinot, 2002; Yokosho et al., 2009). Expression analysis of FRD3 and Os FRDL1 genes indicated that their transcript accumulation is only slightly modulated by iron nutrition (Rogers and Guerinot, 2002; Yokosho et al., 2009). In addition, FRD3 promoter activity and Os FRDL1 protein are localized to the root pericycle (Green and Rogers, 2004; Yokosho et al., 2009). Both the Arabidopsis and rice proteins mediate citrate efflux when produced in Xenopus laevis oocytes (Durrett et al., 2007; Yokosho et al., 2009). Iron staining in the root revealed a strong accumulation of iron in the stele of the Arabidopsis and rice mutants. Consistent with the iron starvation symptoms in leaves (Green and Rogers, 2004; Durrett et al., 2007; Yokosho et al., 2009), citrate and iron concentrations were reduced in xylem exudates. Therefore, it was proposed that the function of FRD3/Os FRDL1 is to release citrate into the root xylem, which would in turn be required for efficient translocation of iron to the shoot. Although protoplasts prepared from frd3 leaves display decreased iron content (Green and Rogers, 2004), total leaf iron is similar in frd3 and wild-type plants (Delhaize, 1996). Thus, in addition to promoting root-to-shoot circulation of iron in the xylem sap, citrate might represent an important ligand for the passage of iron from the apoplast to the symplast in leaf.

In this article, we report that a genetic screen designed to isolate regulatory mutants of iron homeostasis enabled us to isolate a new frd3 allele. It prompted us to clarify the role that FRD3, and by extension, citrate, play in iron allocation and partitioning between apoplast and symplast, and how FRD3 impacts plant development at different stages. We show that FRD3 is strongly expressed in the developing embryo where it is required for efficient germination in iron-limiting conditions. We also demonstrate, using iron histochemical staining, that later in plant development, citrate released by FRD3 in the vascular tissues enables iron solubilization and circulation in the apoplast located around the vascular tissues throughout the plant, and promotes iron mobilization to the cells adjacent to the leaf veins. Finally, we observed that frd3 mutants display a drastic fertility defect caused by an alteration of pollen development, itself resulting from shortage of soluble iron in the anther locule. Based on these data, we propose a model in which citrate efflux mediated by FRD3 allows iron solubilization in the apoplastic space separating two tissues without symplastic connections. Our results indicate that this process likely provides available iron to sustain germination of the embryo, growth of leaf mesophyll cells, and development of the pollen grains.

RESULTS

Isolation and Characterization of Two Novel frd3 Alleles

Screening EMS-mutagenized proIRT1:LUCIFERASE transgenic plants for Arabidopsis mutants that are unable to properly regulate IRT1 promoter activity (see Supplemental Figure 1 online) enabled us to isolate a new frd3 allele called frd3-6 (Figure 1A). Several other loss-of-function alleles of FRD3, named frd3-1, frd3-2, frd3-3/man1, and frd3-5, have been reported (Delhaize, 1996; Rogers and Guerinot, 2002; Lahner et al., 2003) and are shown to have iron homeostasis defects during vegetative growth. Whether the corresponding FRD3 mutant proteins harbor decreased citrate efflux activity or are completely nonfunctional is currently unknown. To explore the precise role of FRD3 in the maintenance of iron homeostasis during plant development, we collected a knockout mutant (SALK_122535), named hereafter frd3-7, carrying a T-DNA insertion within exon 8 (Figure 1A) that completely abolishes FRD3 mRNA accumulation (see Supplemental Figure 1 online).

Figure 1.

Figure 1.

Phenotype of Two New Alleles of FRD3.

(A) Position of frd3-6 and frd3-7 mutations on the FRD3 gene. LB, left border; G → A, guanine to adenine transversion.

(B) Phenotype of 7-week-old frd3-6 and frd3-7 mutants grown in soil. NM, nonmutagenized parental line; WT, wild type.

(C) frd3 chlorosis is reverted by iron supply. Four-week-old frd3-6 plants cultivated on soil were irrigated with water (−Fe) or 0.5 mM FeEDDHA (+Fe).

As for some of the frd3 alleles previously described, frd3-6 and frd3-7 mutant plants showed smaller rosette leaves and severe chlorosis when cultivated in soil in greenhouse conditions (Figure 1B). Their chlorosis was reverted by exogenous iron supply (Figure 1C). Consistent with the literature (Delhaize, 1996; Rogers and Guerinot, 2002; Lahner et al., 2003) and with the increased IRT1 promoter activity in frd3-6 (see Supplemental Figure 1 online), the level of IRT1 and FRO2 mRNAs was increased in frd3-6 and frd3-7 alleles (see Supplemental Figure 1 online).

Role of FRD3 at the Vegetative Stage

Previous reports have established that FRD3 is expressed only in the root, and more precisely, in the pericycle and vascular cylinder (Rogers and Guerinot, 2002; Green and Rogers, 2004). We generated transgenic Arabidopsis plants expressing β-Glucuronidase (GUS) under the control of the FRD3 promoter to determine the FRD3 expression pattern at all stages in the plant’s life. Histochemical analysis of GUS activity showed the presence of strong staining in roots and the absence of staining in leaves (Figures 2A and 2C). In the root, staining was found in the pericycle based on its disappearance upon lateral root formation (Figure 2A), as well as in the root cap (Figure 2B).

Figure 2.

Figure 2.

FRD3 Promoter Activity in Root and Shoot, and Iron Distribution in the frd3-7 Mutant.

(A) to (C) Histochemical GUS staining of proFRD3:GUS plants from a representative transgenic line. (A) and (B) Primary root from a 1-week-old axenically grown plant in the mature zone (A) or the meristematic zone (B). The arrow in (A) shows a developing lateral root. (C) Rosette leaf of a 4-week-old soil-grown plant.

(D) to (L) Perls/DAB staining of thin sections of 4-week-old wild-type (WT; [D], [G], and [J]) or frd3-7 plants ([E], [F], [H], [I], [K], and [L]). Roots ([D] to [F]), hypocotyl ([G] to [I]), and rosette leaves ([J] to [L]) are shown; (F), (I), and (L) are staining negative controls without Perls. c, cortex; cc, cork cambium; cp, cortex parenchyma; e, endodermis; ep, epidermis; p, phloem; vc, vascular cambium; x, xylem; arrowheads in (H) indicate the line of separation between vascular and cork cambium. Scale bars = 50 μm in (D), (E), (I), (J), (K), and (L), 100 μm in (A), (G), and (H), and 200 μm in (B).

Previously, a strong accumulation of iron had been detected in the root vascular cylinder of the frd3-1 mutant (Green and Rogers, 2004). To further identify the cellular compartment of iron location in the frd3-7 root, we stained thin cross-sections of these tissues using the highly sensitive and resolutive Perls-diamino benzidine (DAB) histochemical method (Roschzttardtz et al., 2009). Compared with the negative control (Figure 2F), wild-type roots displayed some deposits of iron around all the stele cells, including pericycle and vascular tissues (Figure 2D). The iron deposits were dramatically increased in frd3-7 roots (Figure 2E). Iron accumulation was typically observed outlining the cells—but not within the cells—of the entire stele region delimited by the casparian strip (Figure 2E). This indicates that accumulation of iron in frd3-7 is restricted to the apoplast, in a region of the root central cylinder enclosed within the casparian strip. This apoplastic iron deposition associated with the decrease of circulating iron and citrate in the xylem sap of the frd3 mutant (see Supplemental Figure 2 online and Durrett et al., 2007) is consistent with citrate being required to solubilize apoplastic iron in the central cylinder.

We then tested whether similar iron precipitation occurred in other organs. In the hypocotyl, we observed elevated iron levels in the vascular cambium of frd3-7 compared with wild-type plants (Figure 2G), with strong Perls/DAB staining in the apoplast surrounding the xylem vessels (Figure 2H). The intensity of the staining tended to decrease in the peripheral vessels. Iron deposits were also detected around the secondary phloem vessels, as well as in the apoplastic space, forming a separation line between vascular and cork cambium. Because the cork cambium is generated by division of the pericycle layer, the presence of iron in this region is reminiscent of the root pattern (Figure 2H). The accumulation of iron in the hypocotyl of frd3-7 is likely an indirect consequence of the lack of FRD3 in the root because the FRD3 promoter is not active in the hypocotyl except very early in development (see below).

The frd3 mutant is chlorotic despite an iron content in leaves that is, depending on the growth conditions, similar to or higher than that of wild-type plants (Delhaize, 1996; Rogers and Guerinot, 2002; Lahner et al., 2003). As for the hypocotyl, no detectable GUS activity driven by FRD3 promoter was detected in leaves (Figure 2C). To pinpoint the cause of the leaf chlorosis in frd3, we performed Perls-DAB histochemical analysis on frd3-7 leaf cross-sections. Strong iron staining was detected in frd3-7 vasculature, particularly around the xylem vessels (Figure 2K), whereas no staining was observed in the vasculature of wild-type plants (Figure 2J). Conversely, the amount of symplastic iron in mesophyll cells decreased in frd3-7 compared with wild type (Figures 2J and 2K). This result establishes that in the absence of FRD3 activity, iron precipitates in the vascular cells of the leaf and fails to enter the mesophyll, thus inducing leaf chlorosis.

Collectively, these results show that in the absence of FRD3 in the root, deposition of iron likely due to iron precipitation occurs in the apoplast of vascular tissues throughout the vegetative parts of the plant. This result further supports a role for citrate efflux in solubilization of the apoplastic iron pool stored around the vascular tissues, and points to an important function of citrate in the process of iron unloading from xylem vessels and its subsequent entry into the symplast of leaf cells.

Role of FRD3 during Germination

The frd3-7 mutant showed slow root growth and chlorotic cotyledons as early as 1 to 3 d after germination, specifically in conditions of iron deficiency (Figures 3A and 3D). Identical defects were observed for frd3-1 (Figure 3B) and frd3-6 (see Supplemental Figure 3 online) alleles. This observation revealed that in addition to its function in iron mobilization in xylem, FRD3 is also necessary for early development. Iron supplementation fully rescued the frd3-7 phenotype, increasing by over twofold its root growth (Figure 3D), thus strongly suggesting that germination of the frd3 mutant is limited by iron availability. However, this phenotype is neither explained by a decrease of iron in the seed (Figure 3E), nor by a defect of iron distribution as revealed by Perls/DAB staining of wild-type and frd3-7 dry seed embryos (Figures 3F and 3G). To test the hypothesis that it is the absence of citrate excretion that causes improper iron nutrition of frd3 embryos, germination of frd3-7 was performed in the presence of citrate. This treatment significantly rescued the phenotype of frd3-7 plants, which showed regreening of the cotyledons (Figure 3C, + Cit) and higher root growth (Figure 3D) under iron deficiency. This result clearly supports the idea that citrate efflux by FRD3 contributes to iron nutrition of the embryo during the early stage of germination. GUS histochemical analysis of ProFRD3:GUS lines showed that the FRD3 promoter is active throughout the embryo, during its maturation prior (Figures 4A and B), and after (Figure 4C) seed desiccation. This is consistent with the elevated FRD3 mRNA accumulation measured in siliques (see Supplemental Figure 4 online). Cross-sections of the embryo at the dry seed stage showed staining of all the tissues, with a more pronounced coloration in the protodermis layer (Figure 4G). During the early stages of germination, GUS staining was restricted to the cotyledons, and to a lower extent, to the hypocotyl (Figures 4D and 4E). At the emergence of the first pair of leaves, GUS staining faded away in the cotyledons and appeared in the root stele (Figures 4F and 4I). Interestingly, the envelope of the seed showed strong GUS staining in the aleurone layer (Figure 4H). It is noteworthy that during embryogenesis and early germination, FRD3 is primarily expressed in the cell layers, in the embryo and the seed coat, that are facing the space surrounding the developing embryo. This observation, associated with the early phenotypic defect of germination of the frd3 mutant, strongly suggests a role for citrate efflux in iron mobilization at this stage of development.

Figure 3.

Figure 3.

FRD3 Is Required for Efficient Germination in Iron-Deficient Conditions.

(A) and (B) Chlorosis and reduced size of 3-d-old frd3-7 (A) and frd3-1 (B) seedlings grown under iron deficiency (no added iron) compared with wild-type (WT) plants.

(C) and (D) Citrate supplementation partially rescues the germination defect of the frd3 mutant. Wild-type and frd3-7 plants were grown for 3.5 d under iron sufficiency (50 μM FeEDTA, +Fe) or iron deficiency (no added iron) in the presence or absence of 3 mM Na citrate (+Cit) as indicated. Citrate treatment rescues frd3-7 chlorosis (C) and root growth defect (D). Scale bars = 1 mm.

(E) Iron content in wild-type and frd3-7 seeds. Error bars = SD.

(F) and (G) Iron localization in wild-type (F) and frd3-7 (G) dry seed embryos assayed by Perls/DAB histochemical staining.

Figure 4.

Figure 4.

The FRD3 Promoter Is Active during Embryogenesis and the Early Stages of Germination.

GUS histochemical staining of a representative proFRD3:GUS transgenic line.

(A) to (C) Dissected embryos from green siliques ([A] and [B]) or a dry seed (C).

(D) to (F) Seedling after 1 d (D), 3 d (E), or 5 d (F) of germination.

(G and H) Longitudinal section of a dry seed showing the embryo (G) or the seed envelope (H).

(I) Close-up image of the hypocotyl-root transition zone of a 5-d-old seedling. Scale bars = 50 μm

FRD3 Is Also Required at Reproductive Stages

As mentioned earlier, frd3-7 plants are chlorotic and show reduced growth when cultivated in the greenhouse in long-day conditions (Figures 1B and 5A). Moreover, frd3-7 plants were essentially sterile, with very few siliques formed (Figure 5B) and a seed yield as low as 2% of that of wild-type plants (Figures 5C and 5D). Irrigation of the plants with iron (500 μM Fe-EDDHA) suppressed frd3-7 chlorosis (Figures 5A and 5B). Iron treatment also rescued frd3-7 silique development (Figure 5B) and increased seed production by sevenfold in iron-supplied frd3-7 plants compared with only 2.3-fold in wild-type plants (Figure 5C). Unlike chlorosis and sterility, however, the impaired growth of the mutant was not rescued by iron supplementation (Figure 5A). Instead, iron treatment exacerbated frd3 dwarfism, suggesting that additional iron supply to the already iron-overloaded frd3 mutant is toxic.

Figure 5.

Figure 5.

Phenotype of the frd3 Mutant at the Reproductive Stage.

Wild-type and frd3-7 plants were grown for 8 weeks in soil irrigated with water or 500 μM FeEDDHA.

(A) to (E) Phenotypic defects of the frd3-7 mutant and their rescue by iron. Chlorosis (A), production of altered siliques (B), reduced seed production (C), and absence of flower opening ([D] and [E]). Elongated (normal) and nonelongated (mutant) siliques are labeled with arrows and arrowheads, respectively (B). The graph (C) represents the mean of two independent experiments, each performed with six to eight plants. Error bars = SD. WT, wild type.

[See online article for color version of this figure.]

Inflorescences from water-irrigated frd3-7 plants showed chlorotic flower buds that fail to open at stages 12 to 13 (Figure 5, compare D with E). As in rosette leaves of other frd3 alleles (Delhaize, 1996; Rogers and Guerinot, 2002; Lahner et al., 2003), metal content in the inflorescence of the frd3-7 mutant showed an increase in Mn and Co, as well as a decrease in iron (Table 1). When frd3-7 plants were supplemented with iron, inflorescences regreened and flowers opened (Figure 5F). This suggests that the defect in flower development in frd3-7 is caused by insufficient iron in the inflorescence. Altered fertility was also observed with two other frd3 alleles, frd3-1 and frd3-6 (see Supplemental Figure 5 online), strongly supporting the view that FRD3 directly or indirectly plays a role in plant reproduction.

Table 1.

Elemental Analysis of Wild-Type and frd3-7 Inflorescences (mg/kg dry weight)

Mn Zn Fe Co
Genotype Mean SD Fold Change Mean SD Fold Change Mean SD Fold Change Mean SD Fold Change
Wild type 115 22 215 105 55 12 0.52 0.07
frd3-7 250 42 2.2** 205 11 0.95 39 5.3 0.71* 0.66 0.08 1.27*

Inductively coupled plasma-mass spectrometry measurement in inflorescences of wild-type and frd3-7 plants grown in soil (n = 4). Significant differences between frd3-7 and wild type are indicated as *P < 0.05 and **P < 0.01, n = 4. One representative experiment (n = 2) is shown.

Frd3-7 Is Defective in Pollen Development

To correlate FRD3 expression pattern with the fertility abnormality of frd3-7, we investigated GUS activity in the flowers of ProFRD3:GUS transgenic plants. FRD3 promoter activity was found in the flower, restricted to the male gametophyte (Figures 6A and 6B). Cross-sections through the anther showed blue staining in the anther tissue and in the pollen grains (Figure 6C).

Figure 6.

Figure 6.

FRD3 Promoter Activity in Flower.

GUS histochemical staining of an inflorescence of a representative pFRD3:GUS transgenic line.

(A) Inflorescence.

(B) Anther and stigmatic papillae.

(C) Longitudinal section of a stamen. Scale bars = 100 μm.

The finding that the FRD3 promoter is strongly and specifically active in the male part of the flower prompted us to further characterize the impact of the loss of FRD3 on flower development and to examine pollen development in the frd3-7 mutant. frd3-7 flowers showed a defect in anther structure and lacked pollen grains at the anther surface compared with wild-type plants (Figures 7A and 7B). Microscopic analyses of the anther revealed that pollen grains are produced in frd3 mutant plants but their viability is drastically reduced to 5% of the wild type (Table 2). Staining with Alexander’s stain, which labels viable pollen in pink and dead pollen in blue, confirmed the presence of rare viable pollen grains in the mutant (Figures 7C and 7D). We next tested whether the frd3-7 pollen phenotype is associated with low iron nutrition by irrigating the mutant with iron (500 μM FeEDDHA, see Methods). The morphology of the pollen grains was examined by staining with periodic acid-Schiff-naphthol blue-black thin cross-sections of frd3-7 anthers. Compared with water-irrigated plants that produced a majority of aborted pollen grains (Figure 7E, Table 2), the anthers of iron-treated plants developed 100% normal pollen grains (Figure 7F, Table 2), demonstrating that the phenotype of the mutant is caused by an alteration of iron nutrition of the pollen grains.

Figure 7.

Figure 7.

Pollen Development Is Impaired in frd3-7.

(A) and (B) Detailed view of a wild-type (WT; [A]) and an frd3-7 flower (B), highlighting the morphological difference of the frd3-7 anthers.

(C) and (D) Pollen viability assay in wild-type (C) or frd3-7 anthers (D) using the Alexander’s stain. Viable and dead pollen grains are stained in pink and blue, respectively.

(E) and (F) Periodic acid-Schiff-naphthol blue-black–stained cross sections of mature flowers collected from frd3-7 plants irrigated (F) or not (E) with 0.5 μM FeEDDHA. Arrowhead, normal pollen; asterisk, abnormal pollen; ep, epidermis; en, endothecium; ps, pollen sac. Scale bars = 50 μm in (E) and (F) and 100 μm in (C) and (D).

Table 2.

Pollen Viability in the frd3 Mutant

−Fe +Fe
frd3-7 genotype Normal Pollen (%) Abnormal Pollen (%) Normal Pollen (%) Abnormal Pollen (%)
+/+ 100 0 100 0
−/− 5 95 100 0
+/− 52 48 n.d. n.d.

Percentage of normal and abnormal pollen estimated in naphtol blue black-stained sections obtained from five to 10 flowers of two individual plants from two independent experiments. Plants were irrigated with water (−Fe) or 0.5 mM FeEDDHA (+Fe) to rescue pollen development. n.d., not defined.

frd3-7 Pollen Phenotype Results from a Gametophytic Mutation

Because FRD3 is expressed in pollen and in sporophytic tissues, including root and anther, and because all of the aerial parts of the frd3 mutant are chlorotic, we asked whether the defect in pollen development is the consequence of the loss of FRD3 expression in the sporophyte, the gametophyte, or both. To that end, we took advantage of the fact that, as frd3-7 is a recessive mutation, development of the frd3-7/FRD3 heterozygous plant appears phenotypically wild type at the vegetative or reproductive stages. We sought to determine whether the 50% of haploid pollen grains that carry the frd3 mutation in the FRD3/frd3-7 background harbor a typical frd3 developmental defect. Anthers from unopened flowers were sectioned at an early stage, i.e., prior to tapetum degeneration (Figure 8A), or at a mature stage when tapetal cells are gone (Figure 8B). At the early stage, pollen grains produced by frd3-7/frd3-7 plants looked smaller than pollen grains from FRD3/FRD3 anthers and had a collapsed cellular content (Figure 8G). Later on, the same pollen grains looked like debris of dead cells outlining the walls of the pollen sac (Figure 8H). In addition to the pollen defect, the tapetum of the frd3-7/frd3-7 flowers contained noticeably expanded and vacuolated cells compared with wild-type tapetum (Figures 8A and 8G). When looking at frd3-7/FRD3 anthers, we observed an equivalent number of both types of pollen grains (Table 2), wild-type, round shaped-pollen, and frd3-like collapsed pollen, despite the normal aspect of surrounding anther tissues (Figure 8E). This indicates that the developmental defect of frd3 pollen is independent of the maternal tissues and primarily depends on the gametophytic expression of FRD3.

Figure 8.

Figure 8.

The frd3 Mutation Acts Gametophytically to Alter Pollen Development.

(A) to (I) Histological sections of flowers from wild-type FRD3/FRD3 ([A] to [C]), heterozygous FRD3/frd3-7 ([D] to [F]), or homozygous mutant frd3-7/frd3-7 plants ([G] and [H]) stained with periodic acid-Schiff-naphthol blue-black ([A], [B], [D], [E], [G], and [H]) or with Perls/DAB ([C], [F], and [I]).

(A), (D), and (G) Immature anther containing pollen at the two-cell stage.

(B), (C), (E), (F), (H), and (I) Mature anther containing trinucleated pollen before dehiscence. Arrowhead, normal pollen; asterisk, abnormal pollen. Scale bars = 50 μm.

We next looked at the iron accumulation pattern in anthers of FRD3/FRD3, frd3-7/FRD3 and frd3-7/frd3-7 plants through Perls/DAB staining of thin flower sections (Figures 8C, 8F, and 8I). In the homozygous mutant anther, strong deposits of iron were observed in the anther locule that appeared to be located on the surface of the collapsed pollen grains (Figure 8I). No such iron accumulation was detected in the locule of wild-type anthers (Figure 8C). Consistently, the frd3-7/FRD3 heterozygous anthers presented iron deposits that were restricted to the population of aborted pollen grains (Figure 8F). This result strongly suggests that the loss of FRD3 in pollen prevents iron solubilization outside pollen and subsequent iron acquisition.

DISCUSSION

Previous studies had suggested a role for FRD3-mediated citrate efflux in the root-to-shoot translocation of iron in xylem vessels (Rogers and Guerinot, 2002; Green and Rogers, 2004; Durrett et al., 2007; Yokosho et al., 2009). Here, we report on important additional functions of FRD3 and citrate in the mobilization of iron in seed and flower. We found strong expression of FRD3 throughout the embryo, early in the maturation process, as well as in the pollen grain. Consistently, loss-of-function mutations in FRD3 alter germination in iron-limiting growth conditions and dramatically reduce fertility. We found that the sterility of frd3 mutants is caused by a defect in pollen development, dependent on FRD3 gametophytic expression, which correlates with a decrease of iron inside the aborted pollen grains and the presence of iron deposits on their surface. In addition, we have refined the location of iron in root and shoot of the frd3 mutant and identified that leaf chlorosis is caused by retention of iron in the apoplast surrounding the vessels from the root up to leaf vasculature and by the resulting decrease of iron in its target organelles in leaf mesophyll cells.

In frd3 roots, iron deposits were observed specifically in the apoplastic zone, whereas symplastic iron remained unchanged, which supports the current view that citrate efflux in the apoplast is necessary to solubilize iron in the extracellular space. Iron accumulation is restricted to the stele, i.e., the region contained within the boundaries of the casparian strip, which therefore acts as a tight barrier for iron circulation. Consequently, to penetrate into the stele, iron must take a symplastic route. Candidates for iron entry in the symplast of the external layers are primarily IRT1 in the epidermis and cortex (Vert et al., 2002) and Natural Resistance-Associated Macrophage Protein1 in the endodermis (Cailliatte et al., 2010). A second consequence is that cells of the stele must have iron efflux activity to provide the apoplastic compartment with iron. Ferroportin 1 (FPN1) is an iron and cobalt efflux transporter that is expressed in the root central cylinder where it might participate in metal loading of the xylem sap (Morrissey et al., 2009). Therefore, we reasoned that if FRD3 and FPN1 act synchronously to efflux citrate and iron, respectively, knocking out FPN1 in the frd3 background would prevent accumulation of iron in the stele and rescue frd3 phenotype. However, Perls staining indicated that the deposition of iron in the root of the frd3 fpn1 double mutant was similar to that in the frd3 single mutant (see Supplemental Figure 6 online).

At the vegetative stage, we observed high amounts of iron deposited in the vascular tissues not only of roots, but also of other organs such as hypocotyl and leaf, despite the absence of expression of FRD3 in these tissues. In the hypocotyl, iron was found to accumulate mostly around the xylem. In leaf vasculature too, a dramatic iron accumulation was observed in xylem. Concomitant with the increase of iron in leaf xylem, mesophyll and xylem parenchyma cells showed a loss of the intracellular iron. This was already suggested by the reduction of iron content in frd3 leaf protoplasts (Green and Rogers, 2004). However, iron imaging provides the final proof that in frd3, iron does not enter the symplast of leaf cells, which explains the chlorotic symptoms and constitutive root iron uptake activity of the frd3 mutant. Moreover, iron accumulation in frd3 leaf is concentrated in the vascular tissue, while no iron diffusion was observed around mesophyll cells. This result indicates that Fe-citrate in leaf is primarily required for xylem unloading and/or for loading of iron in the cells adjacent to xylem vessels. If Fe-citrate provides iron directly to mesophyll cells, one would expect to observe, in frd3, a local accumulation of iron in the apoplast surrounding these cells. The fact that iron accumulates specifically in xylem, but not around adjacent cells, indicates that xylem parenchyma forms an efficient barrier to apoplastic iron circulation in leaf tissues. It is an interesting question as to whether Fe-citrate enters directly into these xylem-associated cells via an unidentified transport system or whether it donates iron to a ferric-chelate reductase that provides Fe2+ to a leaf-expressed ZRT-IRT LIKE PROTEIN-like family transporter (Figure 9).

Figure 9.

Figure 9.

Model for the Role of FRD3 in Iron Nutrition between Symplastically Disconnected Tissues.

Schematic representation of the proposed role of FRD3 in the different organs at different developmental stages. Top left, FRD3 in the root pericycle is required for solubilization of iron in the apoplast surrounding the stele cells and for proper loading of iron in the xylem sap. This citrate efflux activity might function in coordination with an iron efflux activity from endodermis or pericycle. Top right, Although not produced in leaves, citrate released by FRD3 in the central apoplast of the root is necessary for proper iron loading in the limb cells of the leaf. Bottom left, In the seed, where FRD3 expression is high in the embryo, particularly in the protodermis, and in the aleurone layer of the seed envelope, FRD3 might function to release citrate in the space separating the embryo and the envelope to provide available iron to feed the embryo. Bottom right, in the anther, the pollen grain depends on the pollen expression of FRD3 for its maturation and on the sporophytic expression of FRD3 for optimal ion loading, indicating that citrate efflux in the pollen sac is likely to increase iron solubility and to promote, directly or indirectly, iron acquisition by the pollen grain. In addition, tapetum morphogenesis requires a functional FRD3. In the three latter organs, seed, anther, and leaf, subsequent entry of iron in the sink tissue could occur as an Fe(III)-citrate complex by an as yet unidentified transporter or, after reduction into Fe(II), through a divalent metal transporter of the ZRT-IRT LIKE PROTEIN or Natural Resistance-Associated Macrophage Protein1 families. Because the four above-described situations share the common feature that iron transport from source to sink tissues involves an apoplastic step, we propose that FRD3-mediated citrate efflux is a prerequisite for iron traffic between symplastically disconnected tissues. al, aleurone; e, endodermis; en, endothecium; m, mesophyll cell; p, pericycle; pa, parenchyma; po, pollen grain; pr, protodermis; t, tapetum; x, xylem.

[See online article for color version of this figure.]

In frd3, iron reaches the aerial organs, which suggests that citrate efflux is not necessary for root-to-shoot translocation of iron in xylem sap. In the absence of citrate in the apoplast, free Fe3+ ions likely bind components of the cell wall in the root central cylinder. Because iron uptake is very high in frd3, iron accumulating in the vasculature of the plant may slowly saturate the binding sites in the cell walls, prompting iron to move along the path and gradually reach aerial tissues. Alternately, organic acids, such as malate, that are present in the sap could in theory chelate Fe3+ and promote its translocation to the shoot. Whether such complexes are too inefficient to donate iron to leaf cells, hence, leading to the frd3 chlorotic phenotype, remains an open question. It is worth mentioning that we have not measured any increase of this organic acid in frd3 xylem exudates that could compensate for the decrease of citrate (see Supplemental Figure 2 online).

Although iron supply rescues germination, chlorosis, and fertility of frd3, it does not rescue its growth (Figure 5). It is possible that in addition to being iron deficient, the frd3 mutant suffers from citrate shortage, thereby potentially affecting the numerous metabolic processes in which citrate takes part, including cellular respiration, fatty acid synthesis, and glycolysis. Alternately, iron supply to the frd3 mutant, which already accumulates high levels of iron in the vasculature, might become toxic for the plant and inhibit its growth. This hypothesis is supported by (1) the strong ferritin accumulation in frd3 roots (Green and Rogers, 2004) and (2) the pronounced inhibition of frd3 growth upon iron treatment (Figure 6A).

In addition to the well-known expression of FRD3 in the root, we found strong FRD3 promoter activity in seeds—throughout the embryo, particularly in the protodermis of the cotyledons and hypocotyl-root axis, and in the aleurone layer facing the embryo in the seed envelope. During the first 3 d of germination, growth of frd3 was retarded and its cotyledons were chlorotic in conditions of iron deficiency, a defect that was rescued by iron or citrate supplementation (Figure 3). This strongly suggests that citrate excretion by FRD3 also plays a role in the embryonic iron nutrition during embryogenesis. Because the root is not competent at this stage to take up iron, a possibility exists that cells of the embryonic surface, including cotyledons and hypocotyl, have their own machinery to take up iron that depends on iron availability in the surrounding nutritive fluid. Thus, solubilization of iron by citrate around the embryo could be a prerequisite for direct iron uptake by embryo cells. However, if this is the case, this process is not important for embryo development because we have not observed any morphological alteration of frd3 embryos. It could represent the initial step in the building of the vacuolar iron stores in the endodermis of the embryo (Roschzttardtz et al., 2009); however, the characteristic pattern of embryonic iron was not modified in frd3 embryos (Figure 3). Because loss of FRD3 affects seed germination, its role could be, via the release of citrate from the seed envelope and the embryo, to mobilize putative iron apoplastic stores of the embryo prior to the onset of IRT1 synthesis that occurs 3 d postgermination (Lanquar et al., 2005).

Our analysis shows that FRD3 is required for the development of the male gametophyte and highlights a role for citrate in the process of iron delivery to the pollen grains. frd3-7 flowers produce nonviable aborted pollen grains, unless the plant is irrigated with a solution of iron. The fact that iron supplementation fully rescues frd3 pollen development strongly suggests that iron nutrition of pollen is impaired in the mutant. In addition, it might explain why previous studies have failed to see a fertility defect in frd3 mutant alleles, as iron availability varies greatly according to the soil or culture medium used. Despite our rather iron-limiting growth conditions, we have found that the frd3 mutation is not fully penetrant. Indeed, frd3 plants do set a few seeds (Figure 5C) and viable pollen grains are occasionally observed in the mutant anthers (Figures 7D and 8I).

Despite the FRD3 gene being expressed in the sporophytic and the gametophytic tissues of the anther, we have demonstrated that the frd3 mutation acts gametophytically to affect pollen development. Indeed, heterozygous FRD3/frd3-7 plants harboring phenotypically wild-type inflorescence and anthers display ~50% of aborted pollen grains (Figure 8F, Table 1). Histochemical staining of iron revealed the presence of strong deposits at the surface of the aborted pollen grains in heterozygous and homozygous mutant anthers. It strongly suggests that in the absence of citrate efflux from the pollen grain, iron precipitates at the surface, thereby preventing its uptake by the pollen. Similar to the situation in embryo and leaf vasculature, whether iron enters pollen as Fe-citrate or whether it is solubilized by citrate prior to its reduction and transport as Fe2+ remains an open question.

The role of sporophytic FRD3 in anther and pollen development appears significant as well. The tapetum layer that outlines the pollen sac shows clear cytological alterations as cells exhibit drastically enlarged vacuoles (Figure 8G). Thus, FRD3 is also required for normal development of anther tissue and, in particular, the tapetum. Furthermore, iron content inside the pollen grain, which is clearly visible in wild-type plants, is hardly detectable in the viable pollen grains from heterozygous or homozygous frd3 plants (Figures 8C and 8F). This suggests that the presence of FRD3 in the sporophytic anther tissue contributes to iron nutrition of the pollen grains.

If citrate is released into the anther lumen by tapetal cells and pollen grains, why does pollen from heterozygous plants fail to develop, i.e., why does the sporophytic activity fail to rescue the loss of gametophytic activity? The total amount of citrate released in the pollen sac of the heterozygote might be insufficient to support pollen growth. Indeed, wild-type pollen grains from FRD3/frd3-7 plants contain less iron than do pollen grains from FRD3/FRD3 plants (Figure 8, compare F to C). Consistent with the finding that the pollen developmental defect of frd3 is mostly gametophytic, aborted pollen grains from the heterozygote show iron accumulated on their surface, which suggests that citrate efflux activity is most efficient when present locally around the pollen grain.

Citrate and nicotianamine (NA) are the two well-known iron ligands in plant tissues. Thanks to the existence of the natural NA-less tomato mutant chloronerva, the importance of NA in iron nutrition of developing tissues and in fertility has been shown. As opposed to NA, the precise contribution of citrate in plant iron homeostasis has been difficult to investigate because citrate is a multifunctional metabolite whose depletion would result in pleiotropic effects. Our study, in which the effect of FRD3 suppression has been scrutinized throughout the development of the plant, has provided valuable insights into the iron nutrition pathway during embryogenesis and microsporogenesis and has revealed the decisive contribution of citrate to these processes.

Deciphering the function of FRD3 at the whole plant level has led us to the interesting finding that FRD3 mediated-citrate efflux always occurs toward an extracellular space separating two tissues deprived of symplastic connections. It is the case between pericycle and xylem, as suggested in previous studies, but also between the embryo and the seed envelope, and between pollen and surrounding anther tissues (Figure 9). Therefore, we propose a model in which iron nutrition of such disconnected tissues depends on iron solubilization by citrate outside the cells. From our data emerges a new paradigm in which iron chelation by citrate is a prerequisite step for iron nutrition in extracellular fluids. Recently, complexation of iron by citrate has been proposed as an important event in the blood-to-brain circulation of iron (Moos et al., 2007), thus supporting the view that our model might be generalized to extracellular traffic of iron in eukaryotes.

METHODS

Plant Material and Growth Conditions

Except for frd3-1, which is in the Columbia (Col)-1 ecotype, all the genotypes used are in the Col-0 ecotype. Seeds of the frd3-7 mutant (SALK_122235) were obtained from the ABRC. The frd3-1 allele, obtained in the glabra1 background (Rogers and Guerinot, 2002), was kindly provided by Elizabeth Rogers (U.S. Department of Agriculture/Agricultural Research Service). The frd3-1 fpn1-1 double mutant (Morrissey et al., 2009) was obtained from Mary Lou Guerinot (Dartmouth College). The frd3-6 mutant was obtained from a forward genetic screen of EMS-mutagenized Col-0 plants carrying the ProIRT1:LUCIFERASE transgene (see Supplemental Figure 1 online).

For seed germination experiments, seeds were surface-sterilized and sown on 0.5× Murashige and Skoog medium with Suc, containing (+Fe) or not (−Fe), 50 μM Fe-EDTA and, when indicated in the legend, 3 mM sodium citrate (care was taken to adjust the pH of the medium to 5.7 after addition of sodium citrate) during 3.5 d at 21°C with a 16-h/8-h light/dark cycle. Plants cultivated in the greenhouse were grown on soil (Humin substrate N2 Neuhaus; Klasmann-Deilmann) at 23°C with a sunlight intensity limited to 300 μmol.m−2 s−1 and 16-h light/8-h light/dark cycles.

frd3-7 Molecular Characterization

frd3-7 plants were genotyped by PCR using a T-DNA left border-specific primer (LBb1 5′GCGTGGACCGCTTGCTGCAACT3′) and FRD3 gene-specific primers (5′CCATTGCCCATGTCATTTCTC3′ and 5′ACTAAGTCCTAGGAAGATGAAGAG3′). Segregation on kanamycin revealed a 3:1 ratio characteristic of a single T-DNA insertion. Sequencing of the T-DNA flanking sequences indicated that the eighth exon of FRD3 contains a complex insertion of two or more T-DNA copies (Figure 1C).

ProFRD3:GUS Transgenic Lines

The FRD3 promoter fragment was amplified with the following primers: 5′ACGCGTCGACATGAAAAGGGGAAGTGGCAATG3′ and 5′CATGCCATGGATCTTTTTCCTCTGTAACTG3′, which contain the SalI and NotI restriction sites, respectively. The digested fragment was first cloned in the pRITA vector in translational fusion with the uidA gene encoding the GUS. The proFRD3:GUS cassette was then subcloned into the NotI site of the binary vector pART27 (Gleave, 1992). Twelve independent transgenic Arabidopsis thaliana lines were obtained following floral dip transformation (Clough and Bent, 1998).

Metal Content

Samples were dried for 2 d at 80°C. For mineralization, tissues were digested completely (1–3 h) in 70% HNO3 at 120°C. In seeds, iron content was determined as described in (Lobreaux and Briat 1991). Metal measurement in the inflorescences was performed by inductively coupled plasma-mass spectrometry.

Microscopy Analyses

Histochemical GUS staining was performed as described in (Elorza et al. 2004) using 1 mM 5-bromo-4-chloro-3-indolyl-β-D-glucuronide as a substrate (Jefferson et al., 1987). Flowers were fixed by 30 min of vacuum infiltration followed by 15 h of soaking in a solution containing 2% (w/v) paraformaldehyde, 1% (v/v) glutaraldehyde, and 1% (w/v) caffeine in 100 mM phosphate buffer (pH 7). Flowers were then dehydrated in successive baths of 50%, 70%, 90%, 95%, and 100% ethanol, butanol/ethanol 1:1 (v/v), and 100% butanol, and were embedded in the Technovit 7100 resin (Kulzer) according to the manufacturer’s instructions. Thin sections (3 μm) were cut (Roschzttardtz et al., 2009) and stained with Periodic acid-Schiff’s reagent (Merck) and naphtol blue black (Sigma) to stain carbohydrates and proteins, respectively. After hydrolysis with periodic acid (1% in distilled water) for 5 min, the sections were rinsed with distilled water. In the dark, sections were stained with Schiff’s reagent for 10 min and were then rinsed with a solution containing 0.25% sodium metabisulfite and 0.05N HCl for 2 min. Sections were rinsed with distilled water, stained with naphtol blue black for 15 s (1 g of naphtol blue back, 7 mL of acetic acid, and 100 mL of distilled water), and rinsed with distilled water again. The samples were regressed with acetic acid at 7% and air-dried.

For histochemical iron localization, iron was stained in embryos and in tissue sections using the Perls (fpn1 frd3 mutant) or the Perls/DAB protocol (all the other experiments) following the method described by Roschzttardtz et al. (2009).

Vital staining of the pollen grains was performed by incubating anthers in Alexander’s stain for 15 min (Johnson-Brousseau and McCormick, 2004).

Accession Numbers

Sequence data from this article can be found in Arabidopsis Genome Initiative or GenBank/EMBL databases under the following accession numbers: FRD3, At3g08040; FRO2, At1g01580; and IRT1, At4g19690.

Supplemental Data

The following materials are available in the online version of this article.

Acknowledgments

We thank Elizabeth Rogers (U.S. Department of Agriculture/Agricultural Research Service) for sending the frd3-1 seeds, Mary Lou Guerinot (Dartmouth College) for the gift of the frd3 fpn1 mutant line, Marc Lepetit (Biochimie et Physiologie Moléculaire des Plantes) for his advice on forward genetic screening, Brigitte Touraine for her help with the high-performance ionic chromatography experiments, and Stéphane Mari for helpful discussions. This work was funded by the Agence Nationale de Recherche programs CIDS 06-BLAN-0106 and DISTRIMET 07-BLAN-0110. H.R. was supported by the DISTRIMET 07-BLAN-0110 program and M.S. was supported by the French Ministry of Education and Research.

AUTHOR CONTRIBUTIONS

H.R. and M.S-A. did the research and analyzed data; C.C., J-F.B., and G.V. designed the research; and C.C. wrote the article.

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