INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

Root hairs are long, tubular-shaped outgrowths on the root surface derived from trichoblasts located in the rhizodermis. They are thought to play an important role in the uptake of water and nutrients from the environment by increasing the absorptive surface layer of the root. The development of root hairs is the result of intricate multiple genetic and environmental controls. Pharmacological experiments indicate that phytohormones, in particular ethylene and auxin, appear to be involved in root epidermal cell fate specification. For instance, treatment of seedlings with ethylene or the ethylene precursor 1-aminocyclopropane-1-carboxylic acid (ACC) triggers the development of root hairs, and blocking either ethylene biosynthesis or perception causes a reduction in the frequency of root hairs (Masucci and Schiefelbein, 1994; Tanimoto et al., 1995). Other hormones, e.g. auxin and cytokinin, interact with ethylene metabolism. Alterations in the level or sensitivity of several hormones may therefore affect ethylene-mediated processes. Genetic approaches have also established the connection between plant hormones and root hair development. Auxin-resistant mutants form shorter and fewer root hairs or do not develop root hairs at all (Masucci and Schiefelbein, 1996). Likewise, ethylene overproducing (eto) mutants of Arabidopsis exhibit a higher frequency of root hairs (Smalle and van der Straeten, 1997). Similar results have been obtained with the constitutive triple response (ctr1) mutant, which is affected in ethylene signal transduction (Kieber, 1997, and refs. therein).

Fe is an essential mineral nutrient for plant growth and development. While Poaceae species (grasses) rely on secretion of phytosiderophores (PS) and subsequent uptake of the Fe(III)-PS complex (strategy II; Römheld and Marschner, 1986a), strategy I plants (dicots and non-grass monocots) respond to decreasing Fe in the environment by inducing a series of physiological responses that assist the mobilization of sparingly soluble Fe compounds (Schmidt, 1999). ATPase-mediated acidification of the rhizosphere (Toulon et al., 1992), enhanced activity of a plasma membrane-bound reductase (FRO2; Robinson et al., 1999), and increased expression of a Fe²⁺ transporter (IRT1; Eide et al., 1996; Fox et al., 1996) are ubiquitous responses of strategy I species upon Fe deficiency.

Morphological alterations that result in an increased surface area, such as the formation of root hairs and transfer cells in the rhizodermis, are thought to provide the basis for the physiological reactions. However, views conflict as to the role of root hairs and rhizodermal transfer cells in Fe uptake. While in Ficus benjamina, Fe reduction appeared to be limited to regions of root hair development (Rosenfield et al., 1991), Moog et al. (1995) found no difference with respect to the stimulation of root reduction activity between the root-hair-less Arabidopsis mutant RM57 and its wild type. The physiological importance of root hairs in Fe uptake was also questioned by Chaney et al. (1992). Using chelator-buffered nutrient solutions, the authors showed that root hairs were only developed at severe chlorosis, whereas other responses, e.g. reductase activity, occurred upon imposing intermediate levels of Fe stress severity. It was concluded that the formation of roots hairs is an effect of Fe-deficiency-induced chlorosis, rather than an integral part of the Fe stress syndrome. In contrast to these findings, Landsberg (1994) reported that in sugar beet, transfer cells and root hairs were also induced under latent Fe deficiency.

Ethylene and auxin have been implicated in the regulation of Fe deficiency responses. Fe-stress-induced increases in the synthesis of ethylene and auxin have been reported for both strategy I and strategy II species (Morgan and Hall, 1962; Römheld and Marschner, 1986b; Romera et al., 1999). Disruption of polar auxin transport from the shoot to the root by 2,3,5-triiodobenzoic acid resulted in the inhibition of rhizosphere acidification by Fe-deficient roots. Moreover, inhibitors of either ethylene synthesis or action repress the induction of all components of the Fe stress syndrome in cucumber (Romera et al., 1994) and have been shown to inhibit the uptake of phytosiderophores in barley (Welch et al., 1997). The morphological responses to Fe deficiency can be mimicked by the application of auxin, ethylene, and ABA, leading to enhanced formation of root hairs and, except for ABA, induction of transfer cells in the root epidermis (Romera et al., 1994; Landsberg, 1996; Schmidt and Bartels, 1996). The involvement of hormones in the physiological alterations induced by Fe deficiency is less clear. While Romera et al. (1994, 1999) found a stimulation of all Fe deficiency responses by ACC in several plant species, application of the auxin analog 2,4-dichlorophenoxyacetic acid (2,4-D) to Fe-sufficient Plantago lanceolata roots stimulated root hair growth and transfer cell formation, but their reduction capacity for ferric chelates appeared to be only slightly increased (Schmidt and Bartels, 1996).

To understand how the expression of the physiological and morphological reactions to Fe deficiency stress are regulated, we examined several hormone-related Arabidopsis mutants for their ability to adapt to suboptimal Fe availability. The responses we focused on included root hair formation and root reductase activity. As a further objective, we sought to determine whether the formation of transfer cells in the root epidermis is coupled to the development of root hairs.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

Plant Materials and Growth Conditions

The cin1 and cin2 Arabidopsis mutants were kindly provided by J. Kieber (University of Illinois, Chicago), the cri1-1 mutant was obtained from C. Bellini (Institut National de la Recherche Agronomique, Versailles, France), cpc from K. Okada (Kyoto University, Japan), ers1-1 from E.M. Meyerowitz (California Institute of Technology, Pasadena), eti5 from M.A. Hall (University of Wales, Aberystwyth), nit1-3 from B. Bartel (Rice University, Houston), rgr1 from D. Söll (Yale University, New Haven, CT), sur1 from M. van Montagu (Universiteit Gent, Belgium), and tir3-1 from M. Estelle (Indiana University, Bloomington). The other genetic stocks were obtained from the Arabidopsis Biological Resource Center (Ohio State University, Columbus). Plants were ecotype Columbia unless stated otherwise. All mutants have been described elsewhere (see Table I).

View this table: [in this window] [in a new window]   Table I.   Characteristics of root hairs and reductase activity in wild-type and mutant plants The intensity of the staining by +Fe and Fe plants is indicated by + and  symbols. Fe-sufficient wild-type roots, showing virtually no activity during the experimental period, was defined as , the intensity of the reaction of Fe wild-type and mutant roots was indicated by using the following scale in the order of increasing activity: + < ++ < +++ < ++++. Values in parentheses indicate intermediate levels of intensity.

Plants were grown in a growth chamber on an agar medium as described by Estelle and Somerville (1987). The seeds were surface-sterilized by immersing them in 96% ethanol for 7 min and 30% (v/v) NaOCl for 10 min, followed by four rinses in sterile distilled water. The medium was composed of 5 mM KNO₃, 2 mM MgSO₄, 2 mM Ca(NO₃)₂, 2.5 mM K₂PO₄, 70 µM H₃BO₃, 14 µM MnCl₂, 1 µM ZnSO₄, 0.5 µM CuSO₄, 10 µM NaCl, 0.2 µM Na₂MoO₄, solidified with 0.7% agar. Suc (43 mM) and 2-(N-morpholino)-ethanesulfonic acid (MES; 4.7 mM) were included and the pH was adjusted to 6.0. Seeds were placed onto Petri dishes containing agar medium and kept for 3 d at 4°C in the dark, before the plates were transferred to a growth chamber and grown at 21°C in continuous light (150 µmol m² s¹, TL lamps, Philips, Eindhoven, The Netherlands). After 10 d, plants were grown for an additional 4 d either with 40 µM FeEDTA (+Fe plants) or without Fe and 100 µM 3-(2-pyridyl)-5,6-diphenyl-1,2,4-triazine sulfonate (FerroZine) (Fe plants). 2,4-D was added to the medium after autoclaving from a stock dissolved in ethanol. ACC was added after autoclaving the medium.

Fe(III) Chelate Reductase

Root ferric reductase was quantified using FerroZine to chelate the reduced Fe. Spatial localization of Fe(III) reductase was determined by embedding the roots of seedlings in an agar (0.7%, w/v) medium containing 0.5 mM CaSO₄, 0.5 mM FerroZine, and 0.5 mM FeEDTA for 20 min. Quantitative determination of root reduction activity was performed as described previously (Schmidt, 1994), except that FerroZine was used instead of bathophenanthrolinedisulfonate as a ferrous indicator. Reduction activity was measured by following the changes in A₅₆₂. Reduction rates were calculated using an extinction coefficient of 25,200 M¹ cm¹.

Activity staining for ferric chelate reductase was performed for +Fe and Fe plants of each genotype, with three independent runs with three plants per plate. The concentration of the agar medium allowed the removal of plants without any damage to root epidermal cells.

Microscopy

Analysis of root hair patterns was performed by light microscopy with and without differential interference contrast optics. Photomicrographs were recorded on Kodak 100 Gold negative film (Eastman-Kodak, Rochester, NY).

Electron Microscopy

Roots were cut into approximately 1-cm-long segments and then washed in 0.5 mM CaSO₄. The segments were fixed overnight in 0.1 M potassium phosphate buffer, pH 7.4, containing 0.2% (w/v) glutaraldehyde and 1.5% (w/v) paraformaldehyde. After being rinsed three times in 0.1 M potassium phosphate buffer, pH 7.4, the tissue was dehydrated through a graded ethanol series of 20%, 40%, and postfixed in 0.25% (w/v) osmium tetroxide for 2 h in 40% ethanol at 4°C. Root segments were washed again in 40% ethanol (three times for 10 min) and treated in a solution of 0.3% (w/v) uranyl acetate in 40% ethanol for 2 h at 4°C. The material was washed again twice in 40% ethanol (10 min each) and once in 50% ethanol for 10 min. The samples were then dehydrated in an ethanol series of 75%, 90%, and two times 100% for 30 min each, infiltrated with LR White resin, and polymerized at 50°C for 24 h in vacuo.

Ultrathin sections were cut with a microtome (Ultracut E, Reichert, Vienna) and stained with uranyl acetate and lead citrate. Semithin sections were stained with toluidine blue. Sections used for electron microscopy were examined in an electron microscope (EM 902, Zeiss, Jena, Germany).

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

Fe Deficiency Affects Peculiarities and Patterning of Root Hairs

The patterns of root hairs differ among the genotypes under investigation. Under ordinary conditions, all auxin-related mutants and one of the ABA mutants, abi5-1, developed fewer root hairs than the wild type (Table I). An increased number of root hairs was observed in the ctr1 and eto mutants. In wild-type roots and most of the tested mutants, root hairs were almost exclusively located over anticlinal walls between adjacent cortical cells (Fig. 1). Ectopic hairs, i.e. hairs located over periclinal cortical cell walls, formed in the eto, ctr1, gl2, and ttg mutants. In gl2 and ttg, hairs were formed on almost every root epidermal cell. The TTG and GL2 genes are thought to be positive regulators of non-hair cell fate (Schiefelbein et al., 1997, and refs. therein).

View larger version (99K): [in this window] [in a new window]   Figure 1.   Cross-section of an Fe-sufficient Arabidopsis root. Root hairs are located over anticlinal cortical cell walls. This section was stained with toluidine blue.

Similar to other species, Fe deficiency substantially increased both the length and number of hairs in Arabidopsis roots (Fig. 2). This response was already evident 24 h after the onset of Fe-deficient conditions. Root hair formation was increased in all of the mutants investigated, including the eto genotypes, which are densely covered with root hairs even under ordinary conditions. In the gl2 and ttg1 mutants, growth in Fe-free medium caused an elongation of root hairs. An extension of root hairs was also observed in the axr2 mutant, which had almost no hair-bearing cells at adequate Fe supply. In Fe-deficient plants, some extra root hairs in ectopic locations were observed, suggesting that ethylene might be involved in Fe-status-dependent patterning of root hairs (Figs. 3 and 7). Applying the ethylene precursor ACC exogenously to Fe-sufficient wild-type plants resulted in an increased formation of root hairs. Compared with those induced by Fe deficiency, ACC-induced root hairs were shorter and the root hair zone differed in shape. While in Fe-deficient roots, the length of the root hairs increased continuously from the apex, ACC-treated plants exhibited a nearly inverse pattern (Fig. 4). A similar shape of root hair formation was evident in the eto3 mutant. A small number of double root hairs was noted in roots of Fe-deficient plants, a feature characteristic of the auxin- and ethylene-resistant axr2 mutant (data not shown).

View larger version (92K): [in this window] [in a new window]   Figure 2.   Fe-Deficiency-induced alterations in root epidermis development. Left, Control root. Right, Root hairs of Fe-deficient roots after 4 d of Fe treatment.

View larger version (94K): [in this window] [in a new window]   Figure 3.   Fe-deficiency-induced formation of root hairs in ectopic positions (*). Wild-type seedlings were grown for 4 d in Fe-free medium.

View larger version (81K): [in this window] [in a new window]   Figure 4.   ACC-induced formation of root hairs. Wild-type seedlings were grown for 4 d on medium supplemented with 50 µM ACC.

Defects in Hormone Metabolism Do Not Inhibit the Induction of Fe(III) Reductase

Root-mediated reduction of mutants was estimated by an arbitrary scale (Table I). This scale was calibrated using the Fe(III) chelate reductase activity of wild-type roots as a standard. The visualization method was used instead of quantitative determination to avoid incorrect results due to a non-linear relationship between reduction activity and unit root weight, which was observed when assaying mutants with extremely small root systems. A further advantage of this method is the ability to examine the pattern of reduction activity in the various mutants. A visualization of ferric reduction by +Fe and Fe plants is shown in Figure 5. No major deviations from this pattern of reduction activity was observed in the mutant ecotypes under investigation. Quantitative analysis of Fe chelate reductase activity of the col-0 ecotype revealed a more than 10-fold increase in reduction rate by Fe deficiency (i.e. from 0.38 ± 0.08 to 4.36 ± 0.67 µmol g¹ fresh weight h¹).

View larger version (128K): [in this window] [in a new window]   Figure 5.   Visualization of ferric reduction activity of Fe-sufficient (A) and Fe-deficient (B) Arabidopsis roots. The resulting Fe(II) is trapped by FerroZine to produce a red product.

When grown under Fe-deficient conditions, Fe(III) chelate reductase activity was up-regulated in all genotypes under investigation (Table I). However, a number of mutants displayed either a more or a less pronounced reaction compared with the wild type. Interestingly, most of the cytokinin-related mutants exhibited a slightly (cin1 and cin2) or markedly (cyr1 and cri1) reduced coloration of the test assay. Since the cin mutations negatively affect cytokinin-induced ethylene production (Kakimoto, 1998), the response of the cin1 and cin2 mutants might be interpreted in terms of an involvement of ethylene in the induction of ferric chelate reductase activity. However, amp1, which is characterized by an enhanced cytokinin level, was indistinguishable from the wild type with respect to root reduction induced by Fe deficiency. The extremely small root system developed by the cri1 and cyr1 mutants, which may lead to an underestimation of the activity in the agar plates, is a more plausible explanation for the observed effects. This conclusion may also apply to stp1, which also possesses an abbreviated root system.

Of the auxin mutants, those exhibiting a reduced number of root hairs (aux1, axr1, axr4, and aux/axr double mutants) exhibited only a slightly increased reductase activity when grown under Fe conditions. This was particularly true for axr2 roots, which almost lack hairs when grown under adequate Fe conditions. Neither the tir3 mutant (with a defect in polar auxin transport) nor sur1 (with elevated free indole-3-acetic acid levels) showed marked deviations from the wild type, suggesting that auxin is not important for the regulation of ferric reduction. Decreased activity was also observed in fs1, which displays enhanced auxin levels. As in the case of the cytokinin-related mutants, this may be explained by the phenotype of this mutant, which has a very small root system. It should be noted that aux and axr mutants display resistance to various hormones.

Concerning the ethylene mutants, those altered in ethylene sensitivity, such as ein, ers1, and etr1, showed no differences from the wild type with regard to either morphological or physiological responses to low Fe. A slightly less intense staining was noted in the insensitive mutants eir1 and eti5. In eir1, fewer root hairs shorter than those of wild-type plants under Fe conditions developed. All ethylene-overproducing eto mutants and ctr1, which displays a constitutive ethylene response, exhibited a more pronounced Fe-stress reaction. This was true, in particular, for eto3, which was characterized by extremely dense hairs in both growth types (+Fe and Fe). A slightly higher stress response was also observed in the root hair mutants gl2 and ttg, which possessed hairs on nearly all epidermal cells. No significant deviations from the wild type were noted for the ABA mutants (aba and abi).

Fe Deficiency Does Not Induce the Formation of Transfer Cells in Arabidopsis Roots

The differentiation of transfer cells in the rhizodermis is a common response of strategy I plants to suboptimal Fe availability (Landsberg, 1982, 1994; Schmidt and Bartels, 1996). This cell type is characterized by ingrowths of the cell wall resulting in an enhanced surface-area-to-volume ratio. Enrichment of mitochondria and smaller vacuoles relative to ordinary root epidermal cells are additional peculiarities of transfer cells. Representative micrographs of rhizodermal cells in the root hair zone of +Fe and Fe roots are shown in Figure 6. Epidermal cells of both growth types are highly vacuolated. Roots subjected to Fe deficiency did not reveal any major structural differences and exhibited no transfer-cell-like protuberances. Serial sectioning confirmed that transfer cells were neither formed in the meristematic zone nor in the proximal root part. Like non-hair epidermal cells, root hairs of Fe-deficient Arabidopsis plants did not differentiate into transfer cells nor show any wall ingrowths (Fig. 7). Furthermore, wall ingrowths were not observed in ACC- or 2,4-D-treated roots (data not shown).

View larger version (102K): [in this window] [in a new window]   Figure 6.   Epidermal cells of control (A) and Fe-deficient (B) roots; magnification ×28,560. pcw, Peripheral cell wall.

View larger version (86K): [in this window] [in a new window]   Figure 7.   A, Cross-sectioned root hair from an Fe-deficient plant; magnification ×13,860. B, Cross-section of epidermal cells of Fe-deficient roots. Note the root hair cell in ectopic position; magnification ×5,800.

In some cases appositions of secondary wall material were observed in epidermal cells of Fe roots (Fig. 8). In no case was the occurrence of these structures coupled with other characteristics of transfer cells.

View larger version (102K): [in this window] [in a new window]   Figure 8.   Cell wall apposition in an Fe-deficient epidermal cell; magnification ×43,400.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

Role of Hormones in Fe-Deficiency-Induced Root Hair Formation

Increased root hair density is a common response of higher plants to low Fe supply (Schmidt, 1999). Such morphological alterations are also evident in Fe-deficient Arabidopsis roots, indicating that, despite the regular pattern of hair-forming and hairless cells in the root epidermis, cell fate is influenced by environmental Fe availability. In Arabidopsis, root hairs are formed in a position-dependent pattern relative to the underlying cortical cells (Schiefelbein et al., 1997). In wild-type roots, hair-forming cells are always located over the anticlinal walls of two underlying cortical cells. Ectopic hairs, i.e. hairs over periclinal cortical cell walls, are formed in roots of ctr1 and in the eto mutants, due to increased ethylene synthesis (Table I; Kieber, 1997). In Fe-grown plants root hairs are present at the same relative position, implying that ethylene is involved in the regulation of morphological changes associated with the adaptation to low Fe availability. A role for ethylene can also be inferred from the fact that root appearance under Fe stress can be mimicked by supplementing the medium with the ethylene precursors ACC or ethephon (Romera and Alcántara, 1994; Landsberg, 1996; this study). Similar to Fe conditions, ACC treatment causes the formation of ectopic root hairs (Tanimoto et al., 1995; Landsberg, 1996).

Since exogenously applied auxin also mimics the morphology of Fe-deficient roots (Landsberg, 1996; Schmidt and Bartels, 1996), a role for auxin in the induction of morphological alterations in response to low Fe availability may be inferred. The root-hair-less axr2 mutant forms root hairs under both high exogenous auxin (Wilson et al., 1990) and low-phosphorus media (Bates and Lynch, 1996). This holds also true for growth under Fe conditions, although the main response under the latter conditions is root hair elongation rather than an increase in number. Whether auxin acts directly or indirectly via an increase in ethylene production cannot be deduced from the data. Interestingly, ethylene levels are enhanced under both Fe and P conditions, suggesting similarities in the transduction sequence (Lynch, 1998; Romera et al., 1999).

Role of Hormones in the Induction of Fe(III) Chelate Reductase Activity

All surveyed mutants appeared to be capable of responding to Fe-deficiency stress by elevated Fe(III) chelate reductase activity (Table I). The intensity of staining produced by most Fe-grown mutants was indistinguishable from the wild type, suggesting that hormones are not required for the induction of reduction activity. Mutants exhibiting deviations from the wild type are further characterized by alterations in length and density of root hairs. This was particularly evident for axr2, which has almost no root hairs and displayed a small increase in reduction activity, and eto3, which represents the other extreme with respect to root hair density and intensity of reductase staining (Table I). Thus, reductase activity seems to be associated with root surface area rather than with alterations in hormone levels or sensitivity. Exceptions to this pattern were only noted in cases where the mutation causes a highly reduced root system (e.g. cri1, cyr1, and stp1).

These findings support a model in which, unlike the morphological changes, induction of the physiological responses to Fe deficiency stress are not mediated by hormones. This model is supported by the normal Fe stress response of ethylene insensitive mutants (ein2-ein7 and etr) and other hormone-related mutants. The results presented here are at variance with those reported by Romera et al. (1994). However, while the data of the present study do exclude an absolute requirement of hormones for the induction of physiological responses to Fe deficiency, they do not exclude that ethylene can act as enhancer in the transduction of environmental stimuli. Such an enhancer function might be inferred from the relatively low Fe-stress-induced increase in activity of glabra and ttg phenotypes and the normal response of the caprice mutants, which possess fewer root hairs than the wild type under Fe conditions (Table I).

An essential function for auxin in the induction of ferric reductase activity seems unlikely with regard to the present data. Since inhibitors of polar auxin transport have been suggested to interfere with the induction of Fe-deficiency-induced responses (Landsberg, 1982), the normal response of tir3-1, a defect in polar auxin transport, is of particular interest and can be interpreted in this way: The staining of the medium by Fe-grown roots of the auxin overproducer sur1 is indistinguishable from the wild type, which may be judged as further evidence against a possible role of auxin in the regulation of root reduction activity.

Function of Root Hairs in Fe Reduction

Determinations of Fe(III) chelate reductase activity in vivo are usually based on a root fresh weight basis (for an overview, see Moog and Brüggemann, 1994). This is also true for the half-quantitative visualization of root-mediated Fe(III) reduction in agar medium used in the present study. Since the reduction activity is restricted to young, non-lignified root zones, it may be assumed that an increase in surface area by enhanced root hair formation increases the reduction of Fe(III) in the medium. The present results appear to support this assumption. Further evidence comes from a study by Moog et al. (1995) showing that the activity of wild-type Arabidopsis roots was about 2-fold higher than the root-hair-less mutant RM57. With respect to the temporal pattern of induction of the Fe stress syndrome in Arabidopsis, the occurrence of extra root hairs always preceded reduction activity and the development of chlorosis symptoms. Fe-deficiency-induced root hair formation may therefore be regarded as a means to enhance the physiological reactions, and not as a secondary effect of chlorosis, as suggested by Chaney et al. (1992). It should be noted, however, that the present data do not support the idea that the formation of root hairs is a prerequisite for the development of enhanced ferric reduction activity. Even mutants with extremely reduced surface area, e.g. axr2, showed this response under the conditions in our study.

Function of Rhizodermal Transfer Cells in Fe Uptake

The function of transfer cells in the rhizodermis has mainly been inferred from their position and structural features. Aside from the formation of root hairs, the labyrinth-like cell wall of rhizodermal transfer cells provides a possibility to increase the absorptive surface of the root. Epidermal cells in Fe-deficient and ACC-treated roots were indistinguishable from Fe-sufficient control roots, indicating that Arabidopsis cannot initiate transfer cells in the root epidermis. This finding supports our assumption that transfer cells are not necessary for root-mediated reduction of Fe(III) chelates (Schmidt and Bartels, 1996). Appositions of cell wall material have been observed exclusively in Fe roots (Fig. 8). Since the enlargement of the absorptive surface is minor, an adaptive nature of these alterations is not presumed. It is interesting that some plants are genetically equipped to form transfer cells under Fe conditions while others are not. The fine root system of Arabidopsis may be sufficient with respect to the surface available for the uptake of Fe, and therefore it is tempting to speculate that the formation of extra root hairs and transfer cell differentiation represents alternative strategies. More data are necessary to verify this assumption.

	CONCLUSIONS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

Our data strongly suggest that ethylene (and possibly auxin) mediates Fe-deficiency-induced root hair formation. Evidence for this assumption comes from the Fe-like phenotype of roots treated with ACC and the ectopically placed extra root hairs formed under Fe conditions, ACC treatment, and in ethylene-overproducing mutant seedlings. The root hairs induced by Fe deficiency may act as an enhancer for the reduction of ferric Fe, but this does not represent a prerequisite for physiological adaptations. The results described here also indicate that hormones are not required for an increase of Fe(III) chelate reductase activity. We interpret our results to mean that morphological peculiarities induced by Fe deficiency are regulated independently of physiological responses.