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AP2-ERF Transcription Factors Mediate Nod Factor–Dependent Mt ENOD11 Activation in Root Hairs via a Novel cis-Regulatory Motif^[W]

^a Laboratory of Plant Microbe Interactions, Centre National de la Recherche Scientifique–Institut National de la Recherche Agronomique, BP 52627, Castanet-Tolosan Cedex, France
^b Institut Fédératif de Recherche 40 Pôle de Biotechnologie Végétale, BP17 Auzeville, 31326 Castanet-Tolosan, France

⁴ Address correspondence to fniebel{at}toulouse.inra.fr.

	ABSTRACT

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
Rhizobium Nod factors (NFs) are specific lipochitooligosaccharides that activate host legume signaling pathways essential for initiating the nitrogen-fixing symbiotic association. This study describes the characterization of cis-regulatory elements and trans-interacting factors that regulate NF-dependent and epidermis-specific gene transcription in Medicago truncatula. Detailed analysis of the Mt ENOD11 promoter using deletion, mutation, and gain-of-function constructs has led to the identification of an NF-responsive regulatory unit (the NF box) sufficient to direct NF-elicited expression in root hairs. NF box–mediated expression requires a major GCC-like motif, which is also essential for the binding of root hair–specific nuclear factors. Yeast one-hybrid screening has identified three closely related AP2/ERF transcription factors (ERN1 to ERN3) that are able to bind specifically to the NF box. ERN1 is identical to an ERF-like factor identified recently. Expression analysis has revealed that ERN1 and ERN2 genes are upregulated in root hairs following NF treatment and that this activation requires a functional NFP gene. Transient expression assays in Nicotiana benthamiana have further shown that nucleus-targeted ERN1 and ERN2 factors activate NF box–containing reporters, whereas ERN3 represses ERN1/ERN2-dependent transcription activation. A model is proposed for the fine-tuning of NF-elicited gene transcription in root hairs involving the interplay between repressor and activator ERN factors.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
Legumes have the unique capacity to establish symbiotic associations with nitrogen-fixing soil bacteria known as rhizobia, thereby facilitating growth in nitrogen-limiting soils. This endosymbiotic interaction leads to the formation of specialized root organs known as nodules, within which rhizobia reduce atmospheric nitrogen for the benefit of the host plant. Rhizobial infection in temperate legumes such as Medicago and Lotus is usually initiated in root hairs and is concomitant with nodule organogenesis in the root cortex. Rhizobial attachment to the tip of a growing root hair induces curling around the entrapped bacteria, which subsequently enter the plant cell via a plasma membrane invagination and the formation of an intracellular tubular structure called the infection thread. Bacteria divide within the infection thread, which progresses through the outer root cortex toward the newly formed nodule primordium, within which bacteria are released into host cells and subsequently differentiate into nitrogen-fixing bacteroids (Timmers et al., 1999; Gage, 2004).

The success of this symbiotic interaction requires specific and reciprocal signaling between the two partners. In response to flavonoids secreted by host roots, rhizobia produce specific lipochitooligosaccharide signal molecules called Nod factors (NFs) that play a pivotal role in recognition and controlled host root infection (D'Haeze and Holsters, 2002). Purified NFs are sufficient to induce many of the early plant symbiotic responses normally observed during preinfection stages of the interaction. These include rapid ion fluxes, membrane depolarization, specific calcium oscillations, root hair morphogenetic changes, and specific activation of early nodulin genes (Geurts et al., 2005; Oldroyd et al., 2005; Stacey et al., 2006).

The specificity and subnanomolar activity of NFs argue that receptors mediate NF signal transduction pathways in host roots. Based on rhizobial genetic studies, it has been proposed that an initial signaling receptor pathway is required for early preinfection responses, followed by a second entry receptor pathway that is necessary for bacterial root infection and involving a different specificity for NF recognition (Ardourel et al., 1994). Genetic studies conducted with the model legumes Lotus japonicus and Medicago truncatula have led to the identification and cloning of host genes essential for early NF perception/transduction (Geurts et al., 2005; Oldroyd et al., 2005; Stacey et al., 2006). These studies have revealed that NFs are likely to be perceived via LysM domain–containing receptor kinases such as L. japonicus NFR1/NFR5 and M. truncatula NFP (Madsen et al., 2003; Radutoiu et al., 2003; Arrighi et al., 2006). Following perception, NF signal transduction requires a number of essential genes encoding putative ion channels (DMI1/CASTOR/POLUX) (Ané et al., 2004; Imaizumi-Anraku et al., 2005), LRR receptor–like kinases (DMI2/SYMRK/NORK) (Endre et al., 2002; Stracke et al., 2002), and nucleoporins (NUP85 and NUP133) (Kanamori et al., 2006; Saito et al., 2007), all acting upstream of the NF-induced calcium spiking response in root hairs (Miwa et al., 2006). This specific calcium signal is potentially decoded by the calcium- and calmodulin-dependent kinase DMI3 (Lévy et al., 2004; Mitra et al., 2004a), which is required for subsequent signaling steps that lead to the transcriptional activation of early nodulin genes (Charron et al., 2004; Mitra et al., 2004b).

Although significant progress has been made in deciphering the primary signal perception/transduction components of NF signaling, little is known about the mechanisms leading to transcriptional gene activation in response to NFs. Genetic studies have identified two GRAS-type transcription regulators, NSP1 and NSP2, lying downstream of DMI3 and required for subsequent NF-induced gene expression in both Medicago and Lotus (Kaló et al., 2005; Smit et al., 2005; Heckmann et al., 2006; Murakami et al., 2007). Although a direct transcriptional regulatory function has not yet been demonstrated for these factors, it is proposed that they could be coactivators of other DNA binding transcription factors (Udvardi and Scheible, 2005). Most recently, a genetic approach has identified an ERF transcription factor named ERN (for ERF Required for Nodulation) that is necessary for NF-elicited gene activation and could potentially be involved in the direct transcriptional activation of early nodulin genes (Middleton et al., 2007).

In addition to genetic approaches, the direct identification of NF-responsive cis-regulatory elements and trans-acting factors should also contribute to elucidating the molecular mechanisms regulating NF-elicited gene expression. To this end, we have made use of the well-characterized M. truncatula Mt ENOD11 gene as a model to determine the molecular mechanisms of NF-dependent gene regulation (Charron et al., 2004). Mt ENOD11, which encodes an atypical repetitive Pro-rich protein, is a widely used marker gene for both the early preinfection and subsequent infection stages of the symbiotic association (Journet et al., 2001). During preinfection stages, Mt ENOD11, along with Mt ENOD12 and rip1, are the earliest M. truncatula genes characterized to date that are specifically activated in root hairs in response to NFs (Journet et al., 1994; Cook et al., 1995; Charron et al., 2004). NF-elicited Mt ENOD11 transcriptional activation in the root epidermis is both rapid and strong and is dependent on the genetically defined NFP/DMI/NSP NF signaling pathway (Catoira et al., 2000; Ben-Amor et al., 2003; Oldroyd and Long, 2003; Charron et al., 2004; Mitra et al., 2004b; Sauviac et al., 2005).

In a previous article, we showed that the 411-bp Mt ENOD11 promoter sequence directly upstream of the start codon is sufficient to confer both preinfection (NF-mediated) and infection-related expression (Boisson-Dernier et al., 2005). By contrast, the –257-bp truncated promoter is only capable of driving infection-related expression. This finding suggested that the Mt ENOD11 regulatory sequences required for early NF-elicited activation lie within the –411 to –257 promoter region and can be dissociated from the infection-responsive regulatory region. In this study, we have performed a detailed analysis of the –411 to –257 Mt ENOD11 promoter region using deletion, point mutation, and gain-of-function approaches. This has led to the definition of a novel NF-responsive regulatory unit called the NF box and associated regulatory motifs that are necessary and sufficient to confer NF-induced activation in root hairs. Yeast one-hybrid screening of root hair–specific cDNA libraries has identified three NF box binding AP2/ERF transcription factors, including the recently described ERN factor essential for nodulation (Middleton et al., 2007). These transcription factors, named ERN1, ERN2, and ERN3, are highly expressed in root hairs and upregulated by NFs only in the presence of a functional NFP-dependent signaling pathway. Importantly, ERN1 and ERN2 act as transcriptional activators, while ERN3 acts as a putative repressor of NF box–containing target reporters in transiently expressing Nicotiana benthamiana cells. These results led us to propose that ERN factors are key players in the transcriptional regulation of NF-activated early nodulin genes operating via a complex regulatory mechanism involving both repressor and activator factors.

	RESULTS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
The –411 to –358 Mt ENOD11 Promoter Region Mediates NF-Elicited Root Hair Expression
In order to characterize cis-regulatory sequences required for NF-elicited expression in root hairs, we performed a detailed functional analysis of the –411 to –257 Mt ENOD11 promoter region fused to the ß-glucuronidase (GUS) reporter gene in transgenic M. truncatula roots. Because NF-elicited gene activation is restricted to a specific zone of the root epidermis (Journet et al., 2001), a quantitative measurement of GUS activity in entire root extracts frequently underestimates tissue-specific GUS expression in root hairs. For this reason, each construct was analyzed by both fluorimetric and histochemical GUS assays using a large number of independent transgenic roots as described (see Methods) (Boisson-Dernier et al., 2005). In transgenic roots carrying a 2.3-kb Mt ENOD11 promoter fused to the GUS reporter gene (PMt ENOD11-GUS), histochemical GUS activity is totally absent in root hairs of control water-treated roots, whereas a basal activity level is observed in lateral root primordia (Journet et al., 2001; Charron et al., 2004; Boisson-Dernier et al., 2005; Sauviac et al., 2005). This nonsymbiotic expression, detected by fluorimetric assays, has proved useful as an internal control in this study.

Figure 1A illustrates the results of fluorimetric assays performed on a series of 5' promoter deletions between positions –411 and –257 of the Mt ENOD11 promoter. While GUS activity corresponding to basal expression in nonepidermal root tissues was similar for all deletions studied, the capacity to drive NF-elicited expression was dramatically reduced in the –367E11 deletion. This indicates that sequences between –411 and –367 are important for NF-elicited gene activation in root hairs. Furthermore, the fact that the –411E11 promoter deletion lacking sequences between –357 and –258 was still capable of driving NF-elicited gene activation (data not shown) suggests that this region is not essential for the NF-elicited response.

View larger version (19K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 1. Identification of a 54-bp Nod Factor–Responsive Element (NFE) within the Mt ENOD11 Promoter Sufficient to Drive Root Hair–Specific Expression. GUS activity driven by Mt ENOD11 5' promoter deletions and gain-of-function constructs fused to the GUS reporter gene were analyzed in transgenic M. truncatula roots. (A) Schematic representation of Mt ENOD11 5' promoter deletion fusions. Numbers above the promoters indicate the positions of 5' deletions relative to the translation initiation codon ATG. Fluorimetric GUS activities were quantified in root extracts following either water (white bars) or NF (10–9 M) (gray bars) treatment. The percentage values refer to the proportion of NF-induced GUS activity (i.e., after subtraction of the water control value) of a given construct in relation to the –411E11 reference construct. Asterisks indicate statistically significant differences (P < 0.05, Student's t test) compared with the reference –411E11 construct (see Supplemental Table 1 online). (B) Fluorimetric analyses of reporter GUS activities driven by the gain-of-function 4xNFE construct and the control P35S min construct following NF treatments (10–9 M). The asterisk indicates a statistically significant difference (P < 0.05, Student's t test) compared with the reference P35S min construct. Error bars represent ±SD of mean activity values derived from three independent experiments performed with n number of individual roots.

NF-Mediated Gene Activation Requires a Conserved GCC-Like Motif
In order to identify putative cis elements within the NFE region that could be involved in NF-regulated gene expression, we searched for conserved sequences within NFE that are common to other NF-responsive gene promoters. Comparison between NFE and 5' upstream sequences of two other epidermal NF-activated genes, Mt ENOD12 (Journet et al., 1994) and Mt ENOD9 (D. Barker, unpublished data), allowed us to identify NFE-homologous regions within both promoters (Figure 2A ). Promoter deletion analysis further revealed that truncated –534-bp Mt ENOD12 and –552-bp Mt ENOD9 promoters including the NFE-homologous regions were able to direct NF-responsive reporter expression, whereas deletions lacking the NFE-homologous region (–323 bp for Mt ENOD12 and –525 bp for Mt ENOD9) were no longer responsive to NFs (data not shown). As shown in Figure 2A, a striking feature of NFE and NFE-homologous regions is the presence of a perfectly conserved GCAGGCC motif, which is reminiscent of, but not identical to, GCC box motifs (AGCCGCC) (Ohme-Takagi and Shinshi, 1995). This conserved GCC-like motif is located within a particularly AT-rich region, and in the case of NFE, it is flanked by consensus binding sites for CAAT binding and DOF transcription factors (Kusnetsov et al., 1999; Yanagisawa and Schmidt, 1999). Interestingly, DOF and CAAT box sites are also found in the vicinity of the GCC-like motif in the NFE-homologous sequences of both the Mt ENOD12 and Mt ENOD9 promoters. In addition, an HD-ZIP–like binding site overlapping the CAAT box motif and a conserved W box binding site for WRKY transcription factors can be identified within the Mt ENOD11 NFE (Figure 2A).

View larger version (37K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 2. Functional Analyses of Conserved cis Motifs Involved in NF-Elicited Expression. (A) Partial sequence alignment of NFE and NFE-like sequences within the Mt ENOD11, -9, and -12 promoters. Asterisks indicate conserved nucleotides at the given positions. The fully conserved 8-bp GCC-like motif is shaded. Putative W box (GTCA), HD-ZIP–like (AAATAATTG), CAAT box (CAAT or ATTG), and DOF (TAAAG or CTTTA) sequences are indicated by double underlining, underlining, boldface lettering, and boxing, respectively. (B) GUS activity of the –411E11 reference and derived constructs block-deleted within the conserved GCC-like and/or G(A/T)-rich motifs of NFE. The relative strength of root hair–specific GUS activity was visually screened in individual NF-treated roots (see Methods) and is represented as the percentage of roots exhibiting clear-cut GUS activity in the root hairs. GUS activity levels were also measured by fluorimetric assays in protein extracts from either water-treated (white bars) or NF-treated (gray bars) roots. The percentage values refer to NF-elicited GUS activities (i.e., after subtraction of the water control value) relative to that obtained with the –411E11 reference construct. (C) Quantitative analysis of GUS activity driven by the –411E11 construct and its mutated derivatives. Substituted nucleotides are shown in italics and underlined. The percentage values refer to NF-induced GUS activities relative to the reference construct. In (B) and (C), error bars represent ±SD and asterisks indicate significant differences compared with the reference construct (P < 0.05, Student's t test) (see Supplemental Table 1 online). n represents the number of individual transgenic roots analyzed.

In order to address the importance of individual cis elements within the NFE region, base substitutions were introduced at sites overlapping or in the proximity of the GCC-like motif. For this purpose, we generated –411E11 derivative constructs mutated in the central GGCC core (GC_core) as well as in the HD-ZIP–like/CAAT box and DOF sites (see Methods) (Figure 2C). These experiments confirmed that, as for the block deletion, the specific mutation of the GC_core (mGC_core) results in a major reduction (>10 fold) in NF-elicited GUS activity, similar to the levels for control roots (Figure 2C; see Supplemental Table 1 online). Although less striking than with the GC_core mutation, a significant threefold to fivefold reduction of the NF-mediated response was also observed in roots transformed with the mDOF and mHDZ constructs, suggesting that these flanking sequences also partially influence the efficiency of the NF-dependent response. Importantly, none of these point mutations modified the nonsymbiotic GUS activity levels in roots (Figure 2C; see Supplemental Table 1 online).

Taken together, these results underline the importance of the GCC-like GCAGGCC motif with its GC_core sequence for NF-elicited expression in root hairs. This central GC-rich sequence may function in cooperation with neighboring cis elements, which together form a fully functional regulatory unit. This particular combination of cis motifs, therefore, could constitute a promoter signature for NF-elicited gene expression in root hairs.

The NF Box Defines a Novel Regulatory Unit Sufficient for NF-Elicited Gene Activation
To further evaluate to what extent these motifs are sufficient to direct NF-elicited expression in root hairs, additional gain-of-function experiments were performed. For this, tetramers of two promoter fragments of 30 bp in length derived from either the 5' or the 3' end of NFE were fused to the P35Smin-GUS reporter (Figure 3A ). In agreement with the deletion and point mutation experiments, NF-elicited GUS activity was only observed in roots carrying the 4xNFE3' construct, which includes the GCC-like, HD-ZIP–like/CAAT, and DOF motifs (Figure 3B). Interestingly, a similar level of GUS reporter activity was observed with either the 4xNFE or the 4xNFE3' construct, indicating that NFE3' contains all of the regulatory elements required for the root hair–specific NF response (cf. Figures 1B and 3B). Furthermore, following Sinorhizobium meliloti inoculation, the 4xNFE3' construct driving the P35Smin-GUS reporter was activated during preinfection (NF-dependent) symbiotic stages (data not shown). However, as expected, this construct was unable to drive infection-related expression in either root tissues or the infection zone of the nodule (Boisson-Dernier et al., 2005) (see Supplemental Figure 1 online). Nonsymbiotic expression in lateral root primordia was also absent in roots transformed with this construct (data not shown). Thus, we conclude that the 30-bp NFE3' sequence, renamed NF box, constitutes a novel regulatory unit sufficient to confer NF-dependent root hair–specific expression.

View larger version (27K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 3. The NF Box Confers an NF-Specific Response in the Root Epidermis. (A) Schematic representation of the NFE sequence and associated cis motifs. The sequences NFE5' and NFE3' (NF box) were used to generate the new gain-of-function constructs tested in (B). (B) Histochemical and quantitative analyses of GUS activity directed by gain-of-function 4xNFE5' and 4xNFE3' (4xNF box) constructs. Data are represented as mean values obtained by the analysis of n individual roots from three independent experiments. Error bars represent ±SD. The asterisk indicates a significant difference compared with the reference construct (P < 0.05, Student's t test) (see Supplemental Table 1 online). Bars = 200 µm.

View larger version (75K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 4. Isolation of NF Box Binding Proteins. (A) Band shift experiments using an NF box–containing DNA probe with root hair protein extracts from 6-h water- or NF-treated roots. In competitor lane reactions, 50 to 100 molar excesses of cold NF box or mNF box probes were included. (B) Schematic representation of the one-hybrid strategy used to screen cDNA libraries from NF-treated root hairs using a HIS3 reporter gene under the control of a minimal HIS3 promoter fused to a tetramer of the NF box and expressed in the yeast YM4271 reporter strain. The number of positive clones corresponding to each of the three cDNA classes (NFbB1, NFbB2, and NFbB3) isolated after two rounds of screening and able to grow on 5 mM 3-AT is indicated. (C) Confirmation of the interaction of NFbB1, NfbB2, and NFbB3 with the NF box by retransformation of yeast YM4271 containing the tetramer NF box-HIS3 reporter with the isolated plasmids expressing GAL4-NFbB fusions and control GAL4 plasmids. Yeast cells were grown on synthetic dropout (SD) Leu–His– + 5 mM 3-AT medium. (D) Binding specificity of NFbB proteins. YM4721 reporter strains carrying tetramer NF box, tetramer NFE, and trimer p53 cis (p53bs) sequences were transformed with plasmids expressing the mouse GAL4-p53 factor that interacts with the p53 binding site, the NFbBs GAL4-NFbBs proteins, and the water control (–). Yeast growth was examined under either nonselective SD Leu– conditions (–3-AT) or selective SD Leu–His– conditions on medium supplemented with 5 mM 3-AT (+3-AT).

To examine the specificity of the interactions of NFbB1, NFbB2, and NFbB3 with the NF box bait sequence in yeast, the corresponding plasmids were used to transform individual yeast strains harboring HIS3 reporters fused to either the tetramer NF box or the NFE tetramer. As a negative control, we made use of a trimer of the unrelated p53 human binding site (Matchmaker; Clontech) (Figures 4C and 4D). Significant yeast growth was only detected when the three NFbB clones were expressed in the presence of the NF box or NFE HIS3 reporters, but not with the p53 HIS3 reporter (Figure 4D). This shows that reporter yeast growth is dependent on the direct interaction of NFbB1, NFbB2, and NFbB3 with NF box–containing target sequences.

NF Box–Interacting Factors Belong to the ERF Transcription Factor Family
Sequence analysis revealed that all positive NFbB clones corresponded to in-frame GAL4AD fusions. NFbB2 and NFbB3 cDNAs are 1098 and 885 bp in length and contain open reading frames of 313 and 238 amino acids, respectively. Positive NFbB1 cDNA clones (857 bp) are all 5' truncated at approximately the 60-bp position and encode a protein of 248 amino acids missing the 20 N-terminal residues. This indicates that the 5' truncated NFbB1 is perfectly able to bind to NF box–containing target sequences in yeast.

Subsequent BLAST analysis revealed that NFbB1, -2, and -3 all belong to the large family of AP2/ERF transcription factors (Riechmann and Meyerowitz, 1998). Furthermore, it turns out that NFbB1 is identical to the symbiosis-associated ERF-like transcription factor called ERN that was recently characterized by Middleton et al. (2007). For simplicity, therefore, we have renamed our three AP2/ERF transcription factors ERN1 (NFbB1), ERN2 (NFbB2), and ERN3 (NFbB3). ERN1, -2, and -3 all contain the highly conserved AP2/ERF domain putatively involved in DNA binding (Wessler, 2005) (Figure 5 ). ERN1 and ERN2 are the most closely related and contain, in addition to the conserved AP2/ERF domain, an identical 22–amino acid stretch at the C terminus that is absent in the ERN3 sequence (Figure 5A). Phylogenetic analysis of the conserved ERN AP2/ERF domain in relation to all known Arabidopsis thaliana family members (http://datf.cbi.pku.edu.cn) shows that the three ERNs, together with Arabidopsis RAP2.11, form a distinct group within the ERF family, as reported for ERN1 (data not shown) (Middleton et al., 2007). A very high level of sequence conservation (80 to 90%) is observed between the AP2/ERF DNA binding domains of all three ERNs and RAP2.11, while there is only 50% conservation between ERN AP2/ERF DNA binding domains and other ERF proteins such as At ERF1 (Figure 5B).

View larger version (46K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 5. NF Box Binding Proteins Named ERN1, ERN2, and ERN3 Belong to the ERF Transcription Factor Family. Comparison of the deduced amino acid sequences of the three entire ERN1, ERN2, and ERN3 proteins (A) and the corresponding AP2/ERF DNA binding domains aligned by ClustalW (Thompson et al., 1997) with those of the related Arabidopsis RAP2.11 proteins (B). Identical amino acid residues are shaded gray. The conserved AP2/ERF DNA binding domain in (A) is underlined, and the 20–amino acid stretch conserved in ERN1 and ERN2 is double underlined. In (B), the conserved AP2/ERF DNA binding domain is indicated. The black wavy bar and arrows represent predicted -helix and ß-sheet regions, respectively, within the AP2/ERF domain of At ERF1 (Allen et al., 1998). Asterisks correspond to conserved amino acid residues required for DNA binding to GCC box motifs.

NF-Elicited Upregulation of ERN Genes in M. truncatula Root Hairs
To study ERN gene expression in M. truncatula root hairs, quantitative RT-PCR analysis was performed on RNA isolated from purified root hairs (Sauviac et al., 2005). As shown in Figure 6A , all three genes are constitutively expressed in untreated roots and root hairs. In all cases, transcript levels are 10-fold higher in root hairs compared with whole root samples. Following NF treatment, both ERN1 and ERN2 genes are upregulated in root hairs and in entire roots, while the level of ERN3 transcripts is not significantly modified. On the other hand, no NF induction of these genes was detected for the nodulation-defective nfp-2 mutant (Figure 6B). This shows that, as for their target gene Mt ENOD11, NF-elicited activation of the ERN genes is dependent on the NFP locus, an essential component of NF perception and signaling in root hairs (Ben Amor et al., 2003; Arrighi et al., 2006).

View larger version (31K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 6. The ERN1, ERN2, and ERN3 Genes Are Upregulated in NF-Treated M. truncatula Root Tissues. (A) Quantitative RT-PCR for ERN1, ERN2, and ERN3 transcripts in total RNA samples extracted from 3-d in vitro grown wild-type intact roots or isolated root hairs treated with either water (white bars) or 10–8 M NFs (gray bars) for 6 h. (B) Quantitative RT-PCR for ERN transcripts in total RNA samples extracted from 3-d aeroponically grown wild-type (A17) or nfp-2 mutant roots treated with either water (white bars) or 10–9 M NFs (gray bars) for 6 h. (C) Quantitative RT-PCR for ERN transcripts in total RNA samples extracted from nitrogen-starved 10-d aeroponically grown wild-type roots (N0) or isolated nodules harvested at 4 d (N4), 10 d (N10), or 14 d (N14) after inoculation. Values represent averages of either two or three independent biological experiments after normalization against EF1 transcript levels (see Methods). Multiplication factors above the shaded bars refer to NF:water expression ratios. Error bars represent ±SD.

Nuclear Localization of ERNs in N. benthamiana Cells
To examine the subcellular localization of the ERN transcription factors, yellow fluorescent protein (YFP) N-terminally fused ERN proteins under the control of the 35S promoter were analyzed in N. benthamiana leaves. As expected, controls expressing a 35S-YFP construct showed fluorescence labeling in both cytoplasmic strands and nucleoplasm (Figures 7A and 7B). Although ERNs do not have a typical nuclear localization signal, our experiments clearly show that YFP-ERN fusion proteins are targeted to the nucleus of transformed cells (Figures 7C to 7H). This is also the case for other AP2/ERF proteins (Lee et al., 2004; Krizek and Sulli, 2006). In addition to the homogeneous nucleoplasm localization observed for all three fusions, the YFP-ERN1 fusion protein was also frequently associated with subnuclear particles (Figure 7D). These subnuclear particles were very dynamic, with an appearance that often varied with time and with a variable frequency between experiments.

View larger version (74K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 7. Nuclear Localization of ERN1-, ERN2-, and ERN3-YFP Fusion Proteins. Confocal images of epidermal N. benthamiana cells expressing control YFP ([A] and [B]), YFP-ERN1 ([C] and [D], YFP-ERN2 ([E] and [F]), and YFP-ERN3 ([G] and [H]) fusion proteins under the control of the 35S promoter. Note the exclusive nuclear localization for the ERN proteins in the nucleoplasm ([C] and [E] to [H]) or in discrete nuclear bodies (D) compared with the cytoplasm (arrows) and the nucleus-localized YFP control ([A] and [B]). In all panels, chloroplast fluorescence appears red. Similar results were obtained with green fluorescent protein (GFP) fusion proteins (data not shown).

View larger version (42K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 8. Transactivation and Repressor Properties of ERN Factors in N. benthamiana Cells. (A) Schematic representation of the 3xHA-tagged ERN effector proteins and the target GUS reporters used for trans-activation studies in A. tumefaciens–infiltrated N. benthamiana cells. The P35Smin-GUS reporter construct alone or fused to the tetramer of the NF box (4xNF box) was used as target GUS reporter. The effector constructs were under the control of the 35S promoter (P35S), and all contained a 3xHA 5' tag upstream of the ERN sequences, deleted (ERN1, ERN2, and ERN3) or not (ERN1, ERN2, and ERN3), for their respective AP2/ERF (AP2) DNA binding domains. (B) to (E) Histochemical and fluorimetric GUS activities of N. benthamiana leaf discs at 24 h following infiltration with the reporters alone (–) or in combination with the different effectors. ERN1 to -3 or ERN1 to -3 effectors were coinfiltrated with P35Smin (B) or 4xNF box ([C] and [D]) target GUS reporters. Transcriptional activation of the 4xNF box reporter in (E) was measured following expression of individual ERN1 or ERN3 effectors or combined expression of ERN1/ERN2, ERN1/ERN3, or ERN1/ERN3 effectors. GUS activity levels were measured using 1 µg of total protein extracts. Error bars represent ±SD of mean GUS activity values derived from either three or four ([B] to [D]) or seven to nine (E) independent experiments. In (E), data are compiled from measurements of 15 to 18 individual samples that were used for Student's t test statistical analysis. Asterisks indicate statistically significant differences (P < 0.05, Student's t test) compared with the reference ERN1 effector construct (see Supplemental Table 2 online).

	DISCUSSION

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
NF-Elicited Gene Activation in Root Hairs Requires a Regulatory Unit with a Novel GCC-Like Motif
Mt ENOD11 is a well-characterized molecular marker that has been widely used to study NF signaling in the root epidermis (Charron et al., 2004; Miwa et al., 2006; Sun et al., 2006; Marsh et al., 2007). In this study, we performed a detailed analysis of the Mt ENOD11 promoter in order to elucidate the molecular mechanisms of NF-regulated gene expression. A gain-of-function approach has shown that a 33-bp promoter sequence that we call the NF box is sufficient to direct specific NF-mediated expression, which is elicited during the early preinfection stage of the S. meliloti association. On the other hand, the NF box alone is not sufficient to confer Mt ENOD11 expression during the later stage of rhizobial infection, which we have previously shown to depend upon a proximal 257-bp promoter region lying downstream of the NF box (Boisson-Dernier et al., 2005). We propose that NF box–mediated gene expression is activated through initial NF perception (via the NFP/DMI/NSP signaling pathway) and that the infection-related expression requires a second distinct signaling pathway that is presumably activated at a later stage before bacterial entry. The NF box sequence is also found in the promoters of other NF-responsive M. truncatula genes such as Mt ENOD12 and Mt ENOD9, which also encode putative Pro-rich cell wall–associated proteins presumably involved in root hair cell wall modification during preinfection stages (Pichon et al., 1992; Journet et al., 2001). It should be noted that the NF box is not present in the 200-bp promoter region of the pea (Pisum sativum) Ps ENOD12B gene that Vijn et al. (1995) have reported to confer NF-elicited expression in dividing cortical cells of the nodule primordia. We suggest that the NF box may be a regulatory unit specifically associated with early NF signaling in the root epidermis. The NF box is also distinct from the recently identified conserved Root Hair Element comprising the strictly conserved CACG motif, which is essential for root hair–specific activation of genes encoding angiosperm cell wall–related proteins (Kim et al., 2006). We thus propose that the NF box acts through an alternative regulatory pathway and therefore may be of interest for engineering novel inducible synthetic promoters for legume-centric research and technology development (Rushton et al., 2002).

Block deletion and point mutation analysis has revealed that a GCC-like (GCAGGCC) motif within the NF box is essential for NF-dependent expression in root hairs and for binding of root hair–specific nuclear protein factors. This motif is reminiscent of, although not identical to, the well-characterized GCC box (GCCGCC) recognized by ERF transcription factors. Despite the lack of the GCC box consensus sequence, a number of essential nucleotides for specific protein binding, indicated in boldface in the GCC box core (GCCGCC) (Hao et al., 1998), can be located to identical relative positions within the NF box (GCAGGCC). Additional studies will now be required to determine the DNA binding specificities of NF box–interacting ERN factors (discussed in more detail below) for this novel variant of the classical GCC box.

Mutations within the CAAT box and DOF-like motifs flanking or partially overlapping the GCC-like motif significantly reduce NF-responsive gene activation, but not as dramatically as mutations within the GCC-like motif. These flanking or overlapping nucleotides can contribute to the binding affinity of transcription factors to the central GC-rich region, as reported previously for other factors (Tournier et al., 2003; Xue and Loveridge, 2004). Alternatively, the GCC-like motif may act in cooperation with neighboring cis motifs to specify expression, as has been reported for a number of plant genes (Buttner and Singh, 1997; Riechmann and Meyerowitz, 1998; Diaz et al., 2002; Brown et al., 2003; Yamamoto et al., 2006). The future characterization of the core cis-regulatory elements specifically recognized by ERN factors should make it possible to scan the M. truncatula genome to discover NF-dependent regulons.

Novel ERF Factors Interacting with the NF Box
Yeast one-hybrid screening using the NF box sequence as bait resulted in the identification of three closely related AP2/ERF transcription factors specifically interacting with this NF-responsive sequence. Interestingly, one of these NF box–interacting ERF factors is identical to the ERN transcription factor very recently identified by a genetic approach (Middleton et al., 2007). The ERN deletion mutant bit1-1 is defective in root infection and nodulation as well as in NF-elicited expression of Mt ENOD11 in root hairs. The three NF box–interacting factors, now named ERN1 (previously named ERN), ERN2, and ERN3, all contain the typical AP2/ERF DNA binding domain and belong to the same phylogenetically related group V of the ERF subfamily that includes Arabidopsis RAP2.11 (Okamuro et al., 1997; Nakano et al., 2006; Middleton et al., 2007). We have shown here that ERN factors bind specifically to the NF box sequence, which contains the essential GCC-like sequence motif (GCAGGCC). Although >10⁷ yeast clones were screened for NF box binding, it is significant that we were only able to identify the three ERN factors, despite the fact that other AP2/ERF clones are represented in the root hair–specific cDNA libraries used for the one-hybrid screen (F. de Carvalho-Niebel and A. Niebel, unpublished data). Taken together, these results argue that ERN-type transcription factors specifically recognize the atypical GCC-like motif within the NF box.

Detailed structural information concerning the interaction between the transcription factor and its target DNA is only available for a few members of the AP2/EREBP family. NMR analysis of the solution structure of Arabidopsis ERF1 bound to the GCC box has revealed that an antiparallel three-stranded ß-sheet binds within the DNA major groove (Allen et al., 1998). This interaction involves direct base contacts with a total of seven amino acids present in the ß-sheet of the conserved AP2 domain of ERF1 (Arg-150, Arg-152, Trp-154, Glu-160, Arg-162, Arg-170, and Trp-172). The AP2 domain of the three ERN factors shares a high level of amino acid identity with that of RAP2.11 but significantly less with ERF1 (Figure 5B). A comparison between the AP2 domains of ERF1 and ERN factors reveals amino acid substitutions at two key positions involved in DNA binding (Trp-154Ser and Arg-162Lys). We propose that these amino acid substitutions modify the binding specificity of the ERN factors and presumably correlate with the atypical NF box GCC-like motif. For example, Fukazawa et al. (2000) showed that the substitution of a highly conserved Arg residue by Lys changes the optimal binding site of the yeast bZIP protein GCN4 from the palindromic site (GACGTC) to the pseudopalindromic site (TGACTCA).

We have demonstrated that the ERN genes are preferentially expressed in root hairs (10-fold higher compared with the whole root) and that in ERN1 and ERN2 are significantly upregulated (7.3- and 3.5-fold, respectively) following the application of purified NFs. Importantly, NF-elicited ERN gene induction is dependent on the NFP genetic locus, an essential component of the NF signaling pathway in the root epidermis, which likely encodes a component of the NF receptor (Ben Amor et al., 2003). Thus, in agreement with similar findings by Middleton et al. (2007), our data support the proposition that ERN factors constitute novel downstream components of the epidermal NF signaling pathway. Interestingly, we note that ERN factors and the Arabidopsis ortholog RAP2.11 appear to be preferentially expressed in root hairs and the differentiation zone of the root epidermis (this study and Genevestigator Gene Atlas; Zimmermann et al., 2004). Furthermore, WIN1/SHN1, another member of the group V Arabidopsis ERF factors, is involved in epidermal surface cuticle biosynthesis and cell wall structural modification (Aharoni et al., 2004; Broun et al., 2004). It is conceivable, therefore, that ERNs may have been recruited from ERF regulatory proteins that function in processes associated with root epidermal cell differentiation.

ERN Factor Interplay May Coordinate NF-Elicited ENOD Gene Activation
As a complement to the yeast one-hybrid–based in vivo system, we studied the transactivation properties of individual ERN factors using a heterologous plant transient expression assay. We have shown that ERN-GFP/YFP fusion proteins transiently expressed in N. benthamiana cells localize to the nucleus, despite the fact that typical nuclear localization signal domains are not present in the predicted protein sequences. It is possible that basic amino acid clusters are responsible for nuclear targeting of ERN factors, as reported for other AP2/ERF proteins (Chen et al., 2003; Krizek and Sulli, 2006; Saleh et al., 2006). We observed that the ERN1 fusion protein is also associated with discrete nuclear bodies (Figure 7). Previous studies have described a similar subnuclear compartmentalization for certain transcription factors and have associated this with functional regulation, including phosphorylation and targeted degradation via the proteasome pathway (Yang et al., 2005; Al-Sady et al., 2006; Saleh et al., 2006). Additional experiments in Medicago roots using native promoter and nuclear domain–associated markers will now be required to further study distinct ERN1 subnuclear localization.

We have found that the nucleus-targeted ERN1 and ERN2 act as positive regulators of the NF box in N. benthamiana cells and that this activity is dependent on the presence of the AP2/ERF DNA binding domain. It should also be noted that ERN1 and ERN2 possess a well-conserved C-terminal sequence that is similar to the C-terminal CMV-4 domain of Arabidopsis and rice (Oryza sativa) RAP2.11 clade members (Nakano et al., 2006), whereas ERN3 lacks this C-terminal sequence and is unable to activate reporter gene expression. Furthermore, when ERN3 is expressed together with either ERN1 or ERN2, there is a clear reduction in transcriptional activation of the 4xNF box reporter, suggesting that ERN3 may function as a repressor-type ERF factor. Coordinated induction of both activator- and repressor-type AP2/ERFs has been proposed to fine-tune the regulation of gene expression and to modulate antagonistic signaling pathways (Fujimoto et al., 2000; McGrath et al., 2005; Nakano et al., 2006).

Our results suggest that activator and repressor ERN proteins function to fine-tune NF-mediated root hair expression of plant genes regulated via NF boxes. In the model presented in Figure 9 , we propose that, in the absence of rhizobia, the highly expressed ERN3 repressor limits the expression of target host genes by binding to the NF box (Figure 9A). Following Rhizobium inoculation, NF signal perception and transduction via the NFP-dependent pathway results in enhanced transcription and protein accumulation of the ERN1 and ERN2 transcriptional activators (Figure 9B). Middleton et al. (2007) has reported that while the ERN1 deletion mutant bit1-1 is defective in nodulation, infection, and Mt ENOD11 gene activation, it is still capable of partial transduction of the NF signal and of limited infection thread initiation. This could be due to partial redundancy with respect to ERN2, which may also be required to regulate NF-elicited ENOD gene activation. The NF-dependent accumulation of ERN1/ERN2 activators may also be accompanied by a change in the level or activity of the ERN3 repressor protein (Figure 9B), although any model to explain this must be consistent with our demonstration that ERN3 transcript levels remain constant following NF treatment. In this respect, it is interesting that ubiquitin-conjugated downregulation of a tobacco (Nicotiana tabacum) repressor-type ERF3 factor has been proposed by Koyama et al. (2003). Additional regulatory steps must be postulated to account for the expression of Mt ENOD11 and other genes in the subsequent steps of infection. Once rhizobia are enclosed within the curled root hair, activation of the entry receptor pathway, essential for bacteria root infection (Ardourel et al., 1994), requires transcriptional factor(s) that mediate Mt ENOD11 expression via the 257-bp proximal promoter region (Boisson-Dernier et al., 2005). We suggest that de novo accumulation of active ERN3 factors may displace ERN1/ERN2 activators from the NF box by an active repressor mechanism (Fujimoto et al., 2000; Ohta et al., 2001; Song et al., 2005), as reported for other class II ERF factors, thus turning off gene expression in adjacent noninfected epidermal cells (Figure 9C). Our findings argue that ERN family members contribute to both positive and negative regulatory fine-tuning of host gene expression during preinfection stages of the legume/Rhizobium symbiotic association.

View larger version (19K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 9. Model for ERN Factor–Mediated Regulation of Early Nodulin Gene Expression in M. truncatula Root Hairs. In the absence of the rhizobial partner, we propose that constitutive binding of ERN3 to the NF box sequence represses Mt ENOD11 gene expression in the root epidermis (A). During the early preinfection stages of the symbiotic association (B), NFs secreted by S. meliloti are perceived and transduced by the NFP-dependent NF signaling pathway. Transcription activation and accumulation of the ERN1/2 activators, probably accompanied by modifications of ERN3 protein levels/activities, lead to transactivation of the Mt ENOD11 gene in root hairs via the NF box regulatory unit (B). Upon bacterial root infection, de novo accumulation of active ERN3 presumably leads to the progressive repression of ERN1/ERN2 transcription activities.

	METHODS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

Treatments of M. truncatula Roots Generated by A. rhizogenes Transformation
Germinated seedlings were inoculated with A. rhizogenes as described by Boisson-Dernier et al. (2001). At 3 weeks after inoculation, composite kanamycin-resistant plants were transferred to pouch paper/Farhaeus agar plates (nitrogen- and antibiotic-free) as described by Boisson-Dernier et al. (2005). Transgenic roots growing on the paper support were treated with either water (control) or an aqueous solution of purified NFs (10^–9 M) or inoculated with a liquid culture of S. meliloti strain RCR2011 (GMI6526) (Ardourel et al., 1994) harboring the hemA-lacZ transgene (5 x 10^–5 bacteria/mL), as described by Boisson-Dernier et al. (2005).

Chimeric Promoter–GUS Constructs
Promoter–GUS Fusion and Deletion Constructs
Mt ENOD12 promoter deletions –531E12 and –327E12 were generated using ScaI and SphI internal restriction sites, respectively. Mt ENOD9 promoter deletions –558E9 and –532E9 were generated by PCR using the 5' primers –549E9-for and –523E9-for (Table 1 ) in combination with the T7 universal primer as 3' primer. Mt ENOD11 promoter deletions –411E11, –367E11, and –257E11 were described previously (Boisson-Dernier et al., 2005). The –350E11 deletion construct was generated by PCR using 350E11-for and 0E11-rev primers (Table 1). The –411E11 construct lacking the –357 to –258 promoter region was obtained by cloning the –411 to –358 promoter region (generated by PCR with primer pairs –411E11EcoRI-for and –358E11HindIII-rev) (Table 1) between the EcoRI and HindIII sites upstream from the –257E11 deletion construct.

Site-Directed Mutagenesis
Motif substitutions within the NF-box sequence were introduced into the –411E11 deletion construct. Point mutations in the HD-ZIP–like motif (AAATAATTG to ACATAAGTG) were obtained by PCR using –411E11EcoRI-for and –367mutHDZ-rev primers (Table 1). The resulting –411 to –367 mutated PCR fragment was cloned into the EcoRI and StuI sites in front of a –367E11 deletion to reconstitute the –411E11mHDZ construct. Substitution in the GC-rich motif (TGCAGGCCT to TGCATATGT) was generated by PCR using primer pairs –411E11EcoRI-for/–367mutGC-rev and –367mutGC-for/–257E11-rev (Table 1). PCR with these primers generated two DNA fragments (–411 to –367 and –367 to –257, respectively) that after restriction digestion with EcoRI/NdeI and NdeI/XbaI enzymes, respectively, were ligated together with the EcoRI/XbaI sites in front of the –257E11 deletion to reconstitute the –411E11mGC_core construct. Substitution in the DOF motif (TAAAG to TGCAG) was introduced by PCR using –367mutDOF-for and –257E11-rev primers (Table 1). The mutated –367 to –257 PCR fragment was subsequently inserted between StuI/XbaI sites of a –411E11 deletion construct to generate the –411E11mDOF construct.

Gain-of-Function Constructs
The tetramers of the NFE region (–411 to –358), of NFE5' (–411 to –380), and of NFE3' (NF box) (–392 to –358) were inserted into EcoRI/HindIII sites upstream from the minimal CaMV 35S promoter (–47) (Pontier et al., 2001). Four tandem copies of each promoter region were obtained as described by Rushton et al. (2002). Briefly, each promoter region (NFE region, NFE5', or NF box) was amplified by PCR using the primer pairs listed in Table 1 to generate for each sequence three PCR fragments named A, B, and C bordered by EcoRI/NheI, XbaI/NheI, and XbaI/HindIII sites. After cloning into the pGEM-T vector (Promega), the resulting plasmids were digested with ScaI (which cuts outside the Mt ENOD11 promoter sequences) together with either NheI (A and B) or XbaI (B and C). Ligation of the digested plasmids 5'-ScaI/NheI-3' and 5'-XbaI/ScaI-3' recreated an intact plasmid with dimers AB and BC of the respective promoter regions. Plasmids AB and BC, which have lost the internal NheI/XbaI sites after ligation, were digested with ScaI/NheI and ScaI/XbaI as before. Ligation of two such fragments then creates the tetrameric ABBC constructs, which were then inserted into the EcoRI and HindIII sites upstream from the minimal –47 CaMV 35S promoter.

All deletion, mutation, and gain-of-function promoter constructs were fused to GUS in the binary vector pLP100 (Szabados et al., 1995) and verified by sequencing using the GUS^–1 primer (5'-TGCCCACAGGCCGTCGAG-3'). pLP100 binary vectors were introduced into A. rhizogenes strain ARqua1 by the freeze-thaw method as described by Höfgen and Willmitzer (1998).

Histochemical and Fluorimetric GUS Assays
Histochemical GUS staining was performed as described previously (Journet et al., 2001) by incubation of transgenic root samples in X-glcA buffer solution (5-bromo-4-chloro-3-indolyl glucuronide, cyclohexylammonium salt; Biosynth). Stained samples were examined with a stereomicroscope (Leica Microsystems) and a Zeiss Axiophot microscope (Carl Zeiss). Double staining for both GUS and ß-galactosidase activities after inoculation with a S. meliloti strain carrying a constitutive hemA-lacZ fusion was performed as described by Vernoud et al. (1999). For enzymatic GUS assays, pools of 7 to 10 independent transgenic roots were ground in liquid nitrogen and homogenized in 1x GUS extraction buffer (50 mM sodium phosphate, pH 7.5, 10 mM 2-mercaptoethanol, 10 mM Na₂EDTA, 0.1% Triton X-100, and 0.1% sodium lauryl-sarcosine) for total protein extraction. GUS activities were measured fluorimetrically using 1 µg of total protein extract as described previously (Boisson-Dernier et al., 2005).

A visual-based quantification method adapted from Sidorenko et al. (2000) was used to evaluate GUS staining intensities for different promoter deletion constructs. Briefly, roots were analyzed at 6 h after staining and classified according to overall visual GUS staining intensities into two distinct categories: moderate/strong staining (+) or undetectable/weak staining (–). For each construct, 40 to 150 independent roots from three separate experiments were analyzed by histochemical and fluorimetric methods. For all constructs tested, there is a linear correlation between the results obtained from the two quantification methods (0.95 < r < 0.98). Statistical data analyses were performed using Student's t test, in which a significant difference was defined for P < 0.05.

Electrophoretic Mobility Shi