- Research article
- Open Access
Two recently duplicated maize NAC transcription factor paralogs are induced in response to Colletotrichum graminicola infection
BMC Plant Biology volume 13, Article number: 85 (2013)
NAC transcription factors belong to a large family of plant-specific transcription factors with more than 100 family members in monocot and dicot species. To date, the majority of the studied NAC proteins are involved in the response to abiotic stress
We have found that two NAC transcription factors, ZmNAC41 and ZmNAC100, are transcriptionally induced both during the initial biotrophic as well as the ensuing necrotrophic colonization of maize leaves by the hemibiotrophic ascomycete fungus C. graminicola. ZmNAC41 transcripts were also induced upon infection with C. graminicola mutants that are defective in host penetration, while the induction of ZmNAC100 did not occur in such interactions. While ZmNAC41 transcripts accumulated specifically in response to jasmonate (JA), ZmNAC100 transcripts were also induced by the salicylic acid analog 2,6-dichloroisonicotinic acid (INA).
To assess the phylogenetic relation of ZmNAC41 and ZmNAC100, we studied the family of maize NAC transcription factors based on the recently annotated B73 genome information. We identified 116 maize NAC transcription factor genes that clustered into 12 clades. ZmNAC41 and ZmNAC100 both belong to clade G and appear to have arisen by a recent gene duplication event. Including four other defence-related NAC transcription factors of maize and functionally characterized Arabidopsis and rice NAC transcription factors, we observed an enrichment of NAC transcription factors involved in host defense regulation in clade G. In silico analyses identified putative binding elements for the defence-induced ERF, Myc2, TGA and WRKY transcription factors in the promoters of four out of the six defence-related maize NAC transcription factors, while one of the analysed maize NAC did not contain any of these potential binding sites.
Our study provides a systematic in silico analysis of maize NAC transcription factors in which we propose a nomenclature for maize genes encoding NAC transcription factors, based on their chromosomal position. We have further identified five pathogen-responsive maize NAC transcription factors that harbour putative binding elements for other defence-associated transcription factors in the proximal promoter region, indicating an involvement of the described NACs in the maize defence network. Our phylogenetic analysis has revealed that the majority of the yet described pathogen responsive NAC proteins from all plant species belong to clade G and suggests that they are phylogenetically related.
NAC transcription factors belong to a large family of plant-specific transcription factors that are expressed in different tissues and at various developmental stages. The founding members of the family, NAM from petunia and ATAF1 and CUC2 from Arabidopsis, were described in 1996 and 1997 [1, 2], and the initials of these genes were used to derive the name for the newly discovered multigene family. To date, 105 NAC genes have been identified in the Arabidopsis genome , 138 in rice , 115 in maize , 113 in sorghum, 177 in soybean and 148 in poplar but only around 40 in lower plants like mosses and spike mosses [5, 6].
The characteristic feature of this group of transcription factors is the presence of a NAC domain at the N-terminus , a stretch of ~160 amino acids highly conserved between the members, which consists of five subdomains A – E . This region serves as a platform for DNA binding, and for homo- or heterodimerizatzion with other NAC proteins [7, 8]. Determination of the NAC domain structure revealed a novel transcription factor fold; a twisted β-sheet enclosed by α-helixes , which was recently shown to interact with the major groove of the target DNA . The C-terminal region, in contrary, is variable in sequence and length and serves as a transcriptional activator [10, 11] or transcriptional repressor .
NAC transcription factors regulate a diverse range of processes in plants. The regulatory role of NACs in the development of plant organs like in the shoot apical meristem [2, 13], the axillary meristem , the cotyledons , lateral roots [11, 12], the xylem [15, 16] or the secondary cell wall [17, 18] has been intensively studied. In addition, it has been described that many members of the NAC transcription factor family coordinate the response to abiotic stress. OsNAC5 and OsNAC6 from rice were shown to be induced by cold, drought and high salinity and to interact with each other and with a third rice NAC transcription factor SNAC1 to induce the expression of stress-responsive genes. Consequently, rice plants overexpressing OsNAC5, OsNAC6, OsNAC10, OsNAC45, SNAC1 and SNAC2 were more resistant to high salt conditions compared to wild type rice plants [19–22]. The expression of OsNAC63 was also strongly induced in rice roots by high salinity and osmotic stress. Arabidopsis plants overexpressing OsNAC63 exhibited a constitutive upregulation of salinity-inducible genes and produced seeds that were more tolerant to both of these stress conditions .
Furthermore, NAC transcription factors are involved in the regulation of senescence in Arabidopsis, where overexpression of AtNAP resulted in early senescence of rosette leaves , and in wheat, where low transcript levels of TaNAM delayed the onset of senescence . In addition, the Arabidopsis NAC transcription factor RD26 is induced by drought and ABA and plants with reduced RD26 expression were insensitive to exogenous ABA treatment, indicating a role of RD26 in ABA-signalling .
In the past decade, NAC transcription factors were also shown to be involved in the regulation of the plant defence network. For instance, the NAC transcription factor ATAF2 acts as a repressor of PR gene expression in Arabidopsis , while ATAF1 negatively regulates the defence response to necrotrophic fungi and bacterial pathogens . Furthermore, ANAC019 and ANAC055 were involved in the JA-dependent expression of defence genes in Arabidopsis . OsNAC6 and OsNAC19 were induced in rice upon challenge with the rice blast fungus M. grisea, and the overexpression of OsNAC6 led to increased resistance towards rice blast [21, 30]. Finally, one potato NAC gene was induced in leaves after inoculation with Phytophthora infestans  and BnNAC1-1, BnNAC5-1 and BnNAC5-7 genes were found to be induced in oilseed rape during flea beetle colonization and Sclerotinia sclerotiorum infection .
To date, data on the expression profile and possible function of maize NAC transcription factors are limited. ZmNAM1 (ZmNAC70 in this report) and ZmNAM2 (ZmNAC35) are expressed in the shoot apical meristem during embryo development, suggesting that they play a similar role as their Arabidopsis and petunia orthologues. Transcripts of ZmNAC4 were detected in developing endosperm, while ZmNAC5 and ZmNAC6, putative paralogues, were expressed in the coleorhiza . Transcripts of two other NAC transcription factors, NRP-1 and Apn-1 were found in the endosperm, the transcript of Apn-1 was also detected in the developing embryo [34, 35]. A group of four NAC transcription factors was shown to be involved in secondary cell wall biosynthesis in maize: ZmSWN1, ZmSWN3, ZmSWN6 and ZmSWN7 were able to complement the phenotype of the Arabidopsis snd1/ nst1 double mutant, which lacks the secondary cell wall in xylem fibers. Overexpression of each of these four maize NAC transcription factors in Arabidopsis wild type led to the ectopic deposition of secondary cell wall, resulting in a curly leaf phenotype similar to that observed for SND1 overexpressing plants, indicating that ZmSNWs are functional orthologues of SND1 .
Although evidence for the involvement of NAC transcription factors in plant defence accumulates, no such data are available for maize yet. Therefore, our aim was to characterize two members of the NAM gene family which we found to be induced in maize leaves challenged with Colletotrichum graminicola. C. graminicola (Cesati) Wilson [teleomorph Glomerella graminicola (Politis)] is a causal agent of anthracnose leaf blight and stalk rot, an economically important disease of maize (Zea mays L.). The C. graminicola infection cycle starts on the leaf surface, where spores germinate. After germination, a specialized infection cell, the appressorium, is differentiated at the tip of the germ tube. The appressorium melanizes and accumulates compatible solutes to develop a high turgor pressure that is subsequently converted into mechanical force to piercing the plant cell wall with the penetration peg. Within the host tissue, the fungus initially produces voluminous primary hyphae that grow biotrophically, i.e. without disrupting the host plasma membrane. This biotrophic phase lasts for approximately 2 days. Subsequently, a switch to necrotrophic growth that involves both a change in lifestyle and hyphal morphology occurs. Spreading of thin, fast growing necrotrophic hyphae, which rapidly colonize and kill the host cells, can be macroscopically observed as extending necrotic lesions. Finally, the pathogen forms acervuli on the surface of the necrotic area, specialized structures mitotically producing conidia, which are distributed to new host tissue by rain splashes [37, 38].
In this study, we provide a systematic nomenclature of the maize NAC transcription factor family, which served as the basis to reveal that the two NACs that were induced in the maize – C. graminicola interaction and other defense-inducible NAC from maize and other plant species are evolutionary related.
Two maize NAC transcription factors are induced in leaves infected with Colletotrichum graminicola
In order to investigate which host genes respond to C. graminicola infection at the different stages of the interaction, we compared the transcriptome of leaves that were spray-inoculated with 2 × 106 conidia/ml to mock-treated control leaves during the biotrophic phase at 36 hpi and after the switch to the necrotrophic phase at 96 hpi by microarray analysis (see ). At 36 hpi, more than 313 genes were differentially regulated (fold change > 2), of which 251 were upregulated in infected leaves. In this set, two genes encoding the putative NAC transcription factors ZmNAC41 and ZmNAC100 were found, which were also induced during the necrotrophic leaf colonization at 96 hpi. To confirm the microarray data, transcript levels of both NAC genes were assessed at 2 and 4 dpi by qRT-PCR (Figure 1). While ZmNAC100 transcripts were induced 4–5 fold, ZmNAC41 was induced 7-fold. As spray-inoculation only led to infection of a fraction of the epidermal cells, the induction of both NACs transcripts is likely significantly higher in the infected cells. To determine the induction kinetics at earlier time points of the interaction, we assessed ZmNAC41 and ZmNAC100 transcript amounts in dip-inoculated leaves, where the proportion of infected tissue is higher compared to spray-inoculated leaves (see Methods section). We employed both C. graminicola wild type (WT) strain CgM2 and mutant strains generated by Agrobacterium tumefaciens-mediated transformation (ATMT), which are affected in virulence to different extent. While fungal penetration was reduced by 50% in mutant AT171, which is weakly affected in virulence (see ), mutant AT416 was unable to efficiently penetrate host tissue and was strongly affected in virulence (Figure 2A). In WT-infected leaves, ZmNAC41 was weakly induced already at the pre-penetration stage at 24 hpi, but massive transcript accumulation coincided with the time of the establishment of biotrophy at 36 hpi (Figure 2B). ZmNAC41 was also induced in the interactions with the two mutants at all tested time points and the expression level was positively correlated with the virulence of the employed strain (Figure 2B). In contrast, the expression of ZmNAC100 was first induced after successful penetration of the WT and the mutant AT171 strain into the host tissue at 36 hpi. In contrast, mutant strain AT416 failed to induce the ZmNAC100 gene (Figure 2C). The timing of infection was confirmed by microscopic observation of the infected leaves (data not shown). Our data demonstrate that ZmNAC100 is induced only upon successful penetration of C. graminicola into the host tissue, which suggests that this NAC could be a part of the induced defence response. Correlation of the expression level of both NACs genes with fungal virulence suggests that they could be a potential compatibility factors in the interaction of maize with C. graminicola.
ZmNAC41 and ZmNAC100are induced by defence signals and during leaf senescence
As both ZmNAC41 and ZmNAC100 responded to biotic stress, we assessed their responsiveness to phytohormones involved in coordinating plant defence response and treated maize leaves with jasmonic acid or 2,6-dichloroisonicotinic acid (INA), an analogue of salicylic acid, or the ethylene precursor 1-aminocyclopropane-1-carboxylic-acid (ACC), a precursor of ethylene. Both transcription factors were induced by jasmonic acid already 10 hours after treatment (hat), and transcripts of ZmNAC100 accumulated further up to 24 hat (Figure 3). Moreover, transcript accumulation of ZmNAC100, but not that of ZmNAC41, was enhanced by exogenously applied INA. These results suggest that ZmNAC41 is specifically induced by JA, and neither ZmNAC41 nor ZmNAC100 responded to ethylene (Figure 3). However, the induction of ZmNAC41 and ZmNAC100 during the compatible interaction with C. graminicola was approx. 100-fold higher as compared to the induction by JA and INA (Figure 3).
Many NAC transcription factors are involved in gene regulation during the senescence program (reviewed by [41, 42]), during which defense-related genes are also induced. Transcript levels of both, ZmNAC41 and ZmNAC100 increased during leaf development and were about 4-fold greater in senescent leaves, as compared to seedlings (Figure 4A).
ZmNAC41 and ZmNAC100are downregulated during salt stress
Some members of the NAC transcription factor family, such as OsNAC6, were described to have overlapping roles in response to both biotic and abiotic stresses . Therefore, we have subjected maize plants to drought or high salinity conditions and evaluated the transcript level of the two NACs genes. Both transcription factors were down-regulated during salt stress and the transcripts of ZmNAC100 also declined during drought stress (Figure 4B). These results demonstrate that both ZmNAC41 and ZmNAC100 are distinctly regulated in biotic and abiotic stress conditions.
Additional maize NAC transcription factors are induced during the defense response
We further analysed, whether other maize NACs are also associated with the defence response. As shown by our transcriptome analysis, ZmNAC15 and ZmNAC97 were weakly induced during the necrotrophic stage of C. graminicola infection (Table 1). From the four NAC genes induced in the C. graminicola maize interaction, only ZmNAC41 was also upregulated in response to the fungal biotroph Ustilago maydis . However, the induction of ZmNAC41 by U. maydis has only been observed at 12 hpi, prior to active defense suppression by the smut fungus . In addition, two other NACs, ZmNAC36 and ZmNAC38 were transcriptionally repressed in the interaction with U. maydis upon tumor formation at 4 dpi.
To identify the regulatory circuitry behind the observed regulation of NAC genes in the two pathosystems, we have scrutinized the upstream promoter regions of the identified maize NAC genes for the presence of binding motifs for defence-associated transcription factors to elucidate if certain promoter elements could confer the specific response towards C. graminicola or U. maydis. All promoters contained a core NAC transcription factor binding site that had been predicted from the promoter element analysis of ANAC019 and ANAC092 . The entire NAC-binding motifs identified for the two Arabidopsis NACs could be found in all analyzed promoters in one to five copies, suggesting that other NAC proteins could bind to the promotors of the analysed NACs as homo- or heterodimers (Table 2). Furthermore, the promoters of all except ZmNAC97, contained binding sites for ERF and TGA transcription factors, which regulate the expression of target genes in response to ethylene or salicylic acid, respectively. A Myc2 binding site, present in the promoters of many jasmonic-acid responsive genes, was found in ZmNAC15, ZmNAC38 and ZmNAC41, while a WRKY-binding motif could be detected in ZmNAC15, ZmNAC36, ZmNAC41 and ZmNAC100. Despite considerable conservation of ERF, TGA, Myc2 and WRKY binding motifs, the promoters of the six analysed NAC genes differ in their individual motif composition. In the proximal region 500 bp upstream of the start codon, putative ERF binding motifs were only present in ZmNAC15 and ZmNAC38, while all potential WRKY binding sites were located in this proximal region. Interestingly, a Whirly-binding motif was found only in ZmNAC41 and ZmNAC100, the only members induced during the early interaction of maize with C. graminicola. In summary, the ZmNAC15, ZmNAC36, ZmNAC38, ZmNAC41 and ZmNAC100 genes all contained potential binding elements for other transcription factors known to be involved in the plant defence network within the proximal promoter region.
Analysis of the family of maize NAC transcription factors
The fact that promoter elements were quite conserved between the six analysed NAC transcription factors prompted us to explore their evolutionary relation. Using the unassembled maize genome information, Shen et al.  identified 177 putative maize NAC genes. Since an assembly of the B73 maize reference genome became available , we analyzed the NAC transcription factor family based on the assembled B73 genome information.
We employed the conserved NAC domain of ZmNAC41 and ZmNAC100 as a query to search against the peptide database (release 5b.60) deposited at http://maizesequence.org. Moreover, gene models for putative maize NAC transcription factors, deposited at Grassius Grass Regulatory Information Server (http://www.grassius.org/index.html), were blasted against the assembled maize genome. As an outcome of both surveys, 116 putative maize NAC genes (excluding alternative splice variants) have been identified, which were renamed using the acronym ZmNAC and ascending Arabic numbers due to chromosomal localisation as a suffix (starting with the short arm of chromosome 1, see Additional file 1: Table S1). Multiple alignment performed on the whole set of putative NAC protein sequences served for the construction of a phylogenetic tree, which revealed that the family can be divided into 12 clades (Figure 5). Phylogenetic trees generated from the entire NAC sequences (Figure 5) were very similar to those obtained from an alignment of the NAC domains only (not shown), indicating that the NAC domains allow for most of the distinction between individual clades.
An alignment of the consensus sequences generated for each clade revealed the typical domain architecture of the NAC proteins. The N-terminal part of the proteins, which includes the NAC domain, was well conserved between the clades, while the C-terminal region was highly divergent even between the members of the same clade (Additional file 2: Figure S1). As described for the Arabidospis and rice NAC transcription factor families [3, 4] and in two surveys using genomic information from 9 and 11 different plant species [5, 6], respectively, five highly conserved subdomains A-E, separated by about 10–20 aa, have been distinguished in the NAC domain (Figure 6). To identify consensus sequences of the subdomains A-E for all clades, the NAC domains of all maize NAC transcription factors were screened with MEME (http://meme.sdsc.edu/meme/cgi-bin/meme.cgi, ). All clades except clade A shared common motifs (cut off p-value 1∙e-10) within the NAC domain (Figure 7). More detailed analysis of these common motifs revealed that the conservation of each motif was higher within the same clade than in the comparison to other clades. As shown for subdomain D (Figure 8), single amino acid residues differed between the individual NAC clades, except for clades C and D, which cannot be distinguished by subdomain D. A high similarity between the NAC subdomains A, D and E was evident between clade A and the other clades, while the NAC subdomains B and C were divergent. Some NAC proteins contained additional motifs in front of the NAC domain. For instance, four members of the clade C shared one leading motif, while another leading motif was present in six members of the clade G and six NACs from other clades.
In the C-terminal part of the protein sequences, in total twenty four distinct motifs (cut off p-value 1∙e-10) have been identified (Figure 7 and Additional file 3: Table S2), some of which were specific to certain clades and subclades as described in the following paragraph. The C-terminus of clade F was distinct from all other clades. First, 6 of 7 clade members contained the QYGAPF motif (motif 12), which is also present in six rice NACs (representing motif 39 in ), and in addition, two different kinds of long C-terminal extensions were present in these members. Furthermore, subfamiliy G has even been divided into three subclades, based on the presence of motif SYDDIQ (motif 10) in subclade G1 and of motif NLDDLQ (motif 27) in subclade G2, which were both absent from the C-terminus of the third subclade. Similarly, one subclade of clade E consisted of six members that all carried a long C-terminal extension that contained three different motifs: ARS (motif 24), IDELS (motif 35) and KIWDWNP (motif 21). Furthermore, 11 members of four different subclades from clade C contained motif TDW (motif 13) and LPLE (motif 30). The latter motif is also present in the C-terminal domains of Arabidopsis and rice NACs (and corresponds to motif iii in ). Finally, the 50 aa motif MAAESNL (motif 9) was specific for four members of clade A, which share between 83% (ZmNAC73 vs. ZmNAC75) and 99% (ZmNAC74 vs. ZmNAC75) homology and appear to be the result of recent duplications.
However, some motifs were shared between members of different clades. Motif 36 (CFS) was present in five members of clades K and J and in some Arabidopsis and rice NACs (representing motif ix/x in ). Furthermore, motif EGSPT (motif 40) was common to members of clades F and K. Motif QT (motif 23) was shared between clades A, B and E, while motif HH/QHH (motif 34) was common to members of clade X, B, C, D and E. The HH/QHH motif is also present in four rice NACs (representing motif 31 in ). Some members of clade X contained motifs that were also found in clade A and B, respectively, which reflects the phylogenetic position of clade X between A and B.
Clade G is enriched in defence-associated NAC transcription factors
Protein sequence comparison showed that ZmNAC41 and ZmNAC100 are closely related; sharing 78% similarity of the whole sequence and 87% in the NAC domain. Thus, these two transcription factors belong to clade G, as revealed by a phylogenetic analysis (Figure 5). Checking the gene duplication data available for maize  further revealed that the two NACs have arisen from segmental duplication between long arms of chromosome 3 (NAC41) and chromosome 8 (NAC100). We were interested to know if the other maize NACs that were associated with defence responses towards the fungal pathogens C. graminicola and U. maydis (see Table 1) are related to ZmNAC41 and ZmNAC100. Phylogenetic analysis revealed that ZmNAC15 and ZmNAC38 were also members of clade G, while ZmNAC36 and ZmNAC97 were divergent from all of the other five proteins, respectively (Figure 5). Including all functionally characterized Arabidopsis and rice NACs to the phylogenetic tree of maize NACs, we found that four Arabidopsis defence-associated NACs also clustered into clade G (Figure 9). Arabidospis ATAF1 was reported to be involved in the defence response against bacterial pathogens and necrotrophic fungi , while the closely related ATAF2 was shown to regulate the expression of PR genes . ANAC019 and ANAC055 were described to be involed in the regulation of the JA-dependent defence response . However, the two only rice NACs that are known to be involved in the response towards biotic stress, OsNAC6 and OsNAC19, were found outside clade G (Figure 8). In summary, eight out of twelve defence-associated NACs from maize, rice and Arabidopsis are members of clade G, while the four other were clustering to the separate families. As of our current knowledge, clade G seems to be enriched in transcription factors involved in response to biotic stress, suggesting that an ancestral NAC of clade G might have acquired its role in defence regulation earlier than NAC proteins from different clades of the family. However, this interpretation is limited by the functional characterization of orthologs of the relevant NAC clades.
The involvement of NAC proteins in the plant defence response network
In this study we have characterised two maize NAC transcription factors; ZmNAC41 and ZmNAC100, which are induced during the interaction of maize with C. graminicola. The accumulation of ZmNAC41 transcript preceeded fungal penetration of the host tissue, suggesting that this transcription factor is activated as a part of the basal defence response. A similar induction pattern was described for the HvNAC6 from barley , which was transcriptionally induced in epidermal cells shortly after inoculation with Blumeria graminis f. sp. hordei (Bgh). Silencing of HvNAC6 reduced penetration resistance and the number of papilla formed in response to fungal penetration . A deletion of ATAF1 in Arabidopsis, an HvNAC6 orthologue, compromised non-host resistance to Bgh, which was shown to be predominantly associated with papilla formation Jensen et al. . Based on these observations, the ZmNAC41, HvNAC6 and ATAF1 orthologs are hypothesized to integrate the early transcriptional events upon PAMP recognition during the basal defence response.
However, the highest accumulation of ZmNAC41 was reached upon successful penetration of C. graminicola into the maize tissue, while the transcription of the other maize NAC transcription factor, ZmNAC100, was exclusively induced during the post-penetration stage of the infection. These data further suggest that both transcription factors described in this study are also associated with induced defence responses at later stages of infection. Induced defence reactions are controlled by phytohormones like jasmonic acid, salicylic acid and ethylene. We have revealed that both maize NAC transcription factors described here are responsive to jasmonic acid, while transcription of ZmNAC100 was also enhanced by salicylic acid, indicating that both transcription factors are indeed involved in phytohormone triggered defence responses. Similarly, it was shown that OsNAC5 and OsNAC6 from rice are strongly induced by methyl jasmonate, although transcripts of both genes accumulated to a similar level as during drought and cold stress . Two Arabidopsis genes coding for NAC transcription factors, ANAC019 and ANAC055 were also responsive to methyl jasmonate, in a COI1- and AtMYC2-dependent manner. Moreover, studies with the anac019/ anac055 double knock-out and overexpression lines revealed that the expression of other JA-responsive genes, like VEGETATIVE STORAGE PROTEIN 1 (VSP1) and LIPOXYGENASE2 (LOX2), is regulated by ANAC019 and ANAC055 , suggesting that these two NAC transcription factors are part of a JA feedback loop. The promoter element analysis of six pathogen induced maize NAC transcription factors in our study has revealed response elements for ERF, WRKY, TGA and NAC transcription factors within 500 bp upstream of the ATG in five of the six analysed genes, suggesting an involvement of these five NACs in the transcriptional network controlling the plant defence response.
Most NAC transcription factors involved in plant defence are phylogenetically related
Interestingly, ATAF1, HvNAC6, ANAC055, ZmNAC41 and ZmNAC100 as well as the two other pathogen inducible maize NAC transcription factors ZmNAC15 and ZmNAC38 belong to NAC clade G. Taking our data and the recent analyses of rice NACs by Nuruzzaman et al.  and Zhu et al.  into account, almost two thirds of all studied defence-induced NAC transcription factors belong to clade G. Interestingly, this clade is one of three evolutionary ancient subclades and contains most of the moss and lycophyte NAC representatives analysed . Physcomitrella patens, the most ancient species harboring NAC transcription factors, possesses genes of the oxylipin pathway like allene oxide synthase (AOS, ), allene oxide cyclase (AOC, ) and lipooxygenase (LOX, ). However, jasmonates have not yet been detected in this moss. Nevertheless, it appears tempting to speculate that one of the first acquired functions of NAC transcription factors might have been the perception of oxylipins since more than 410 million years ago, a time estimate, which is based on the analyses by Zhu et al. .
The comprehensive phylogenetic analysis of 837 NAC transcription factor genes from 9 fully sequenced species of diverse evolutionary position by Zhu et al.  has revealed 21 NAC clades, of which 15 contain maize orthologs. In contrast, our analysis has revealed 12 NAC clades. If we take into account that clade C in our analysis can be divided into two subclades and clade G can be divided into three subclades, our analysis has generated an equal number of discernible clades compared to Zhu et al. . However, the number of clades described in the analysis of Arabidopsis and rice NAC transcription factors [3, 4, 6, 51] deviates from study to study. This indicates that the diversity of the employed genome information determines the computation of NAC clades due to the available number of protein sequences.
In this study, we have identified six maize NAC transcription factors that are induced upon challenge by fungal attack and in silico analysis revealed the presence of promoter elements that supports an involvement of five maize NACs in the defence transcription network. The two members that responded strongly to penetration by C. graminicola and that were studied in more detail, ZmNAC41 and ZmNAC100, were predominantly JA responsive. We have generated a systematic classification of maize NAC genes. On the basis of our phylogenetic analysis, we could reveal that the majority of those NAC transcription factors that have yet been described to be involved in the defence network of higher plants are monophyletic.
In summary, our study adds to a number of previous reports on the involvement of NAC transcription factors in the Arabidopsis, rice and barley defence response. Thus, an increasingly large number of NAC transcription factors seems to be involved not only in the regulation of developmental processes and abiotic stress responses, but also in the regulation of biotic stress responses.
Cultivation of plant and fungal material
Maize plants (Zea mays L.) cv. Nathan were cultivated in phytochambers at a PFD of 400 μE ∙ m-2 ∙ s-1 in a 14 h/10 h light/dark cycle as described by and Colletotrichum graminicola (Ces.) Wils. [teleomorph Glomerella graminicola (Politis)] was grown as described in .
For the infection experiments Colletotrichum graminicola wild type isolate CgM2 of C. graminicola and ATMT-generated pathogenicity mutants  were used. Spores of C. graminicola were washed off from 2 weeks old OMA plates with 1 ml distilled water and diluted to a final concentration of 2 × 104 (low titer) or 2 × 106 (high titer) spores/ml. As specifically stated in the text, fully expanded fourth leaves of two weeks old maize plants were either sprayed with a spore suspension of a high titer (2 × 106 spores/ml), containing additionally 0.02% (v/v) Tween-20 or dipped in a spore suspension of a low titer (2 × 104 spores / ml) for 24 h. Sprayed plants were kept in 100% relative humidity conditions for the next 24 h. Mock-treated leaves were sprayed with 0.02% (v/v) Tween-20 in Milli-Q distilled water or dipped in pure distilled water, respectively. As evaluated by microscopy of acid fuchsin stained leaf material , fungal proliferation was comparable in dip-inoculated and in spray inoculated leaves, although the conidia titer was 100-fold lower in dip-inoculated material. However, dip-inoculation resulted in a much more homogenous infection of the treated leaf segments. Leaves were collected at 24, 36 or 44 h after inoculation, frozen immediately in liquid nitrogen and subjected to further analysis.
Hormone treatments were performed with 1 mM jasmonic acid (JA), 1.3 mM of the SA analog 2,6-dichloroisonicotinic acid (INA), and 5 mM of the ethylene precursor 1-aminocyclopropane-1-carboxylic-acid (ACC). Fourth leaves of two weeks old maize plants were cut submerged in distilled water and incubated in 15 ml 0.2% ethanol containing the indicated hormone concentrations or no addition for mock controls. Leaves were collected after 0, 10 or 24 h of treatment, frozen immediately in liquid nitrogen and subjected for RNA extraction.
Abiotic stress assay
Maize plants were grown with regular watering to 100% field capacity ever other day. Three weeks old plants were subjected to drought and high salinity by withholding water or continuing irrigation with 200 ml of 200 mM sodium chloride. Mock-treated plants were watered as before. After one week of stress treatment, all leaves of each plant were harvested, pooled and subjected for RNA extraction.
Frozen plant material was ground with mortar and pestle in liquid nitrogen to a fine powder and extracted according to the method described by Chomczynski and Sacchi .
1 μg of total RNA was treated with DNase I (Fermentas, St. Leon-Rot, Germany) and RT reaction was performed with Revert Aid™ H Minus Reverse Transcriptase (Fermentas) in total volume of 40 μl according to the manufacturer’s protocol. qRT-PCRs was performed with 1 μl of cDNA from the above RT reactions using 2 × Brilliant II SYBR® Green QPCR Master Mix (Stratagene, Waldbronn, Germany) and 200 nM of upstream and downstream primer each in total volume of 20 μl. The reactions were run on Mx3000P™ System and analyzed with MxPro QPCR Software (Stratagene). Relative transcript amounts of ZmNAC41 were evaluated with forward primer 5′-GATGAAGATGAGTGTCCACGAT-3′ and reverse primer 5′-CCAACCACATACGTATTATCTAACG- 3′ (product size- 149 bp), for ZmNAC100 forward primer 5′-TCTGAGAGTTGCTGTGATGGAA-3′ and reverse primer 5′-TAACCCTTACAAGACTACCAGCAAC-3′ were used (product size – 134 bp). The expression level of both NACs was normalized to transcript level of ZmHMG gene, evaluated with forward primer 5′-GCTTGGTCTCCATGCTTCATCTAA-3′ and reverse primer 5′-CGGTGAAACTGAACTGAACACAAC-3′, giving the 130 bp product. Target gene transcript amounts were normalized to ZmHMG and were calibrated to reference samples as indicated in the respective figure legends.
For transcript profiling, the microarray data described by Voll et al.  were employed.
Maize sequences were downloaded from http://www.maizesequence.org (Release 5b.60) and from the Grassius Grass Regulatory Information Server (http://www.grassius.org/index.html). Arabidopsis sequences were obtained from the Arabidopsis Information Resource (TAIR) (http://www.arabidopsis.org/) and rice sequences were downloaded from GreenPhylDB (http://greenphyl.cirad.fr/v1/cgi-bin/greenphyl.cgi).
Multiple alignments of protein sequences were performed with the program ClustalW 2.0  and phylogenetic trees were build using the UPGMA method implemented in the program Geneious Pro 5.4.3  with 100 replicates for bootstrap assessment. Protein sequences were screened for common motifs with MEME Multiple Em for Motif Elicitation (http://meme.sdsc.edu/meme/cgi-bin/meme.cgi) .
All statistical analyses were performed with a two-tailed, unpaired Student’s t test (P < 0.05)
Agrobacterium tumefaciens mediated transformation
Ethylene response factor
hours post infection
Hours post treatment
NAM ATAF1 and CUC2–like transcription factor
Multiple Em for motif elicitation
Quantitative reverse transcription-polymerase chain reaction
Response to dehydration 26
Secondary wall-associated NAC Domain
Souer E, van Houwelingen A, Kloos D, Mol J, Koes R: The No Apical Meristem gene of Petunia is required for pattern formation in embryos and flowers and is expressed at meristem and primordia boundaries. Cell. 1996, 85: 159-170. 10.1016/S0092-8674(00)81093-4.
Aida M, Ishida T, Fukaki H, Fujisawa H, Tasaka M: Gene involved in organ separation in Arabidopsis: an analysis of the cup-shaped cotyledon mutant. Plant Cell. 1997, 9: 841-857. 10.1105/tpc.9.6.841.
Ooka H, Satoh K, Doi K, Nagata T, Otomo Y, Murakami K, Matsubara K, Osato N, Kawai J, Carninci P, Hayashizaki Y, Suzuki K, Kojima K, Takahara Y, Yamamoto K, Kikuchi S: Comprehensive Analysis of NAC Family Genes in Oryza sativa and Arabidopsis thaliana. DNA Res. 2003, 10: 239-247. 10.1093/dnares/10.6.239.
Fang Y, You J, Xie K, Xie W, Xiong L: Systematic sequence analysis and identification of tissue-specific or stress-responsive genes of NAC transcription factor family in rice. Mol Genet Genomics. 2008, 280: 547-563. 10.1007/s00438-008-0386-6.
Zhu T, Nevo E, Sun D, Peng J: Phylogenetic analyses unravel the evolutionary history of NAC proteins in plants. Evol. 2012, 66: 1833-1866. 10.1111/j.1558-5646.2011.01553.x.
Shen H, Yin Y, Chen F, Xu Y, Dixon RA: A bioinformatic analysis of NAC genes for plant cell wall development in relation to lignocellulosic bioenergy production. Bioenerg Res. 2009, 2: 217-232. 10.1007/s12155-009-9047-9.
Olsen AN, Ernst HA, Leggio LL, Skriver K: DNA-binding specificity and molecular function of NAC transcription factors. Plant Sci. 2005, 169: 785-797. 10.1016/j.plantsci.2005.05.035.
Welner DH, Lindemose S, Grossmann JG, Mollegaard NE, Olsen AN, Helgstrand C, Skriver K, Lo LL: DNA binding by the plant-specific NAC transcription factors in crystal and solution: a firm link to WRKY and GCM transcription factors. Biochem J. 2012, 444: 395-404. 10.1042/BJ20111742.
Ernst HA, Olsen AN, Larsen S, Lo Leggio L: Structure of the conserved domain of ANAC, a member of the NAC family of transcription factors. EMBO Rep. 2004, 5: 297-303. 10.1038/sj.embor.7400093.
Duval M, Hsieh TF, Kim SY, Thomas TL: Molecular characterization of AtNAM: a member of the Arabidopsis NAC domain superfamily.Plant Mol Biol. 2002, 50: 237-248. 10.1023/A:1016028530943.
Xie Q, Frugis G, Colgan D, Chua NH: Arabidopsis NAC1 transduces auxin signal downstream of TIR1 to promote lateral root development. Genes Dev. 2000, 14: 3024-3036. 10.1101/gad.852200.
Hao YJ, Wei W, Song QX, Chen HW, Zhang YQ, Wang F, Zou HF, Lei G, Tian AG, Zhang WK, Ma B, Zhang JS, Chen SY: Soybean NAC transcription factors promote abiotic stress tolerance and lateral root formation in transgenic plants. Plant J. 2011, 68: 302-313. 10.1111/j.1365-313X.2011.04687.x.
Takada S, Hibara K, Ishida T, Tasaka M: The CUP-SHAPED COTYLEDON1 gene of Arabidopsis regulates shoot apical meristem formation. Development. 2001, 128: 1127-1135.
Hibara K, Karim MR, Takada S, Taoka K, Furutani M, Aida M, Tasaka M: Arabidopsis CUP-SHAPED COTYLEDON3 regulates postembryonic shoot meristem and organ boundary formation. Plant Cell. 2006, 18: 2946-2957. 10.1105/tpc.106.045716.
Ohashi-Ito K, Oda Y, Fukuda H: Arabidopsis VASCULAR-RELATED NAC-DOMAIN6 directly regulates the genes that govern programmed cell death and secondary wall formation during xylem differentiation. Plant Cell. 2010, 22: 3461-3473. 10.1105/tpc.110.075036.
Zhao C, Avci U, Grant EH, Haigler CH, Beers EP: XND1, a member of the NAC domain family in Arabidopsis thaliana, negatively regulates lignocellulose synthesis and programmed cell death in xylem. Plant J. 2008, 53: 425-436.
Zhong R, Demura T, Ye ZH: SND1, a NAC domain transcription factor, is a key regulator of secondary wall synthesis in fibers of Arabidopsis. Plant Cell. 2006, 18: 3158-3170. 10.1105/tpc.106.047399.
Zhong R, Richardson EA, Ye ZH: Two NAC domain transcription factors, SND1 and NST1, function redundantly in regulation of secondary wall synthesis in fibers of Arabidopsis. Planta. 2007, 225: 1603-1611. 10.1007/s00425-007-0498-y.
Hu H, Dai M, Yao J, Xiao B, Li X, Zhang Q, Xiong L: Overexpressing a NAM, ATAF, and CUC (NAC) transcription factor enhances drought resistance and salt tolerance in rice. PNAS. 2006, 103: 12987-12992. 10.1073/pnas.0604882103.
Jeong JS, Kim YS, Baek KH, Jung H, Ha SH, Choi YD, Kim M, Reuzeau C, Kim JK: Root-specific expression of OsNAC10 improves drought tolerance and grain yield in rice under field drought conditions. Plant Physiol. 2010, 153: 185-197. 10.1104/pp.110.154773.
Nakashima K, Tran LA, Van Nguyen S, Fujita M, Maruyama K, Todaka S, Ito Y, Hayashi N, Shinozaki K, Yamaguchi-Shinozaki K: Functional analysis of a NAC-type transcription factor OsNAC6 involved in abiotic and biotic stress-responsive gene expression in rice. Plant J. 2007, 51: 617-630. 10.1111/j.1365-313X.2007.03168.x.
Takasaki H, Maruyama K, Kidokoro S, Ito Y, Fujita Y, Shinozaki K, Yamaguchi-Shinozaki K, Nakashima K: The abiotic stress-responsive NAC-type transcription factor OsNAC5 regulates stress-inducible genes and stress tolerance in rice. Mol Genet Genomics. 2010, 284: 173-183. 10.1007/s00438-010-0557-0.
Yokotani N, Ichikawa T, Kondou Y, Matsui M, Hirochika H, Iwabuchi M, Oda K: Tolerance to various environmental stresses conferred by the salt-responsive rice gene ONAC063 in transgenic Arabidopsis. Planta. 2009, 229: 1065-1075. 10.1007/s00425-009-0895-5.
Guo Y, Gan S: AtNAP, a NAC family transcription factor, has an important role in leaf senescence. Plant J. 2006, 46: 601-612. 10.1111/j.1365-313X.2006.02723.x.
Uauy C, Distelfeld A, Fahima T, Blechl A, Dubcovsky J: A NAC gene regulating senescence improves grain protein, zinc, and iron content in wheat. Science. 2006, 314: 1298-1301. 10.1126/science.1133649.
Fujita M, Fujita Y, Maruyama K, Seki M, Hiratsu K, Ohme-Takagi M, Tran LS, Yamaguchi-Shinozaki K, Shinozaki K: A dehydration-induced NAC protein, RD26, is involved in a novel ABA-dependent stress-signaling pathway. Plant J. 2004, 39: 863-876. 10.1111/j.1365-313X.2004.02171.x.
Delessert C, Kazan K, Wilson IW, Van Der Straeten D, Manners J, Dennis ES, Dolferus R: The transcription factor ATAF2 represses the expression of pathogenesis-related genes in Arabidopsis. Plant J. 2005, 43: 745-757. 10.1111/j.1365-313X.2005.02488.x.
Wang X, Basnayake BM, Zhang H, Li G, Li W, Virk N, Mengiste T, Song F: The Arabidopsis ATAF1, a NAC transcription factor, is a negative regulator of defense responses against necrotrophic fungal and bacterial pathogens. MPMI. 2009, 22: 1227-1238. 10.1094/MPMI-22-10-1227.
Bu Q, Jiang H, Li CB, Zhai Q, Zhang J, Wu X, Sun J, Xie Q, Li C: Role of the Arabidopsis thaliana NAC transcription factors ANAC019 and ANAC055 in regulating jasmonic acid-signaled defense responses. Cell Res. 2008, 18: 756-767. 10.1038/cr.2008.53.
Lin R, Zhao W, Meng X, Wang M, Peng Y: Rice gene OsNAC19 encodes a novel NAC-domain transcription factor and responds to infection by Magnaporthe grisea. Plant Sci. 2007, 172: 120-130. 10.1016/j.plantsci.2006.07.019.
Collinge M, Boller T: Differential induction of two potato genes, Stprx2 and StNAC, in response to infection by Phytophthora infestans and to wounding. Plant Mol Biol. 2001, 46: 521-529. 10.1023/A:1010639225091.
Hegedus D, Yu M, Baldwin D, Gruber M, Sharpe A, Parkin I, Whitwill S, Lydiate D: Molecular characterization of Brassica napus NAC domain transcriptional activators induced in response to biotic and abiotic stress. Plant Mol Biol. 2003, 53: 383-397.
Zimmermann R, Werr W: Pattern formation in the monocot embryo as revealed by NAM and CUC3 orthologues from Zea mays L. Plant Mol Biol. 2005, 58: 669-685. 10.1007/s11103-005-7702-x.
Guo M, Rupe MA, Danilevskaya ON, Yang X, Hu Z: Genome wide mRNA profiling reveals heterochronic allelic variation and a new imprinted gene in hybrid maize endosperm. Plant J. 2003, 36: 30-44. 10.1046/j.1365-313X.2003.01852.x.
Verza NC, Figueira TR, Sousa SM, Arruda P: Transcription factor profiling identifies an aleurone-preferred NAC family member involved in maize seed development. Ann Appl Biol. 2011, 158: 115-129. 10.1111/j.1744-7348.2010.00447.x.
Zhong R, Lee C, McCarthy RL, Reeves CK, Jones EG, Ye ZH: Transcriptional Activation of Secondary Wall Biosynthesis by Rice and Maize NAC and MYB transcription Factors. Plant Cell Physiol. 2011, 2: 1856-1871.
Bergstrom GC, Nicholson RL: The biology of corn anthracnose. Plant Dis. 1999, 83: 596-608. 10.1094/PDIS.19188.8.131.526.
Mendgen K, Hahn M: Plant infection and the establishment of fungal biotrophy. Trends Plant Sci. 2002, 7: 352-356. 10.1016/S1360-1385(02)02297-5.
Voll LM, Horst RJ, Voitsik AM, Zajic D, Samans B, Pons-Kühnemann J, Doehlemann G, Münch S, Wahl R, Molitor A, Hofmann J, Schmiedl A, Waller F, Deising HB, Kahmann R, Kämper J, Kogel K-H, Sonnewald U: Common motifs in the response of cereal primary metabolism to fungal pathogens are not based on similar transcriptional reprogramming. Front Plant Sci. 2011, 2: 39.
Münch S, Ludwig N, Floss DS, Sugui JA, Koszucka AM, Voll LM, Sonnewald U, Deising HB: Identification of virulence genes in the corn pathogen Colletotrichum graminicola by Agrobacterium tumefaciens-mediated transformation. Mol Plant Pathol. 2011, 12: 43-55. 10.1111/j.1364-3703.2010.00651.x.
Puranik S, Sahu PP, Srivastava PS, Prasad M: NAC proteins: regulation and role in stress tolerance. Trends Plant Sci. 2012, 17: 369-381. 10.1016/j.tplants.2012.02.004.
Singh KB, Foley RC, Oñate-Sánchez N: Transcription factors in plant defense and stress responses. Curr Opin Plant Biol. 2002, 5: 430-436. 10.1016/S1369-5266(02)00289-3.
Döhlemann G, Wahl R, Horst RJ, Voll LM, Usadel B, Poree F, Stitt M, Pons-Kühnemann J, Sonnewald U, Kahmann R, Kämper J: Reprogramming a maize plant: transcriptional and metabolic changes induced by the fungal biotroph Ustilago maydis. Plant J. 2008, 56: 181-195. 10.1111/j.1365-313X.2008.03590.x.
Schnable PS, Ware D, Fulton RS, Stein JC, Wei F, Pasternak S, Liang C, Zhang J, Fulton L, Graves TA, Minx P, Reily AD, Courtney L, Kruchowski SS, Tomlinson C, Strong C, Delehaunty K, Fronick C, Courtney B, Rock SM, Belter E, Du F, Kim K, Abbott RM, Cotton M, Levy A, Marchetto P, Ochoa K, Jackson SM, Gillam B, Chen W, Yan L, Higginbotham J, Cardenas M, Waligorski J, Applebaum E, Phelps L, Falcone J: The B73 maize genome: complexity, diversity, and dynamics. Science. 2009, 326: 1112-1115. 10.1126/science.1178534.
Bailey TL, Elkan C: Fitting a mixture model by expectation maximization to discover motifs in biopolymers. Proceedings of the Second International Conference on Intelligent Systems for Molecular Biology: AAAI Press, Menlo Park, California: 1994, 28-36.
Jensen MK, Hagedorn PH, de Torres-Zabala M, Grant MR, Rung JH, Collinge DB, Ryngkjaer MF: Transcriptional regulation by an NAC (NAM-ATAF1,2-CUC2) transcription factor attenuates ABA signalling for efficient basal defence towards Blumeria graminis f. sp hordei in Arabidopsis. Plant J. 2008, 56: 867-880. 10.1111/j.1365-313X.2008.03646.x.
Nuruzzaman M, Sharoni AM, Satoh K, Moumeni A, Venuprasad R, Serraj R, Kumar A, Leung H, Attia K, Kikuchi S: Comprehensive gene expression analysis of the NAC gene family under normal growth conditions, hormone treatment, and drought stress conditions in rice using near-isogenic lines (NILs) generated from crossing Aday Selection (drought tolerant) and IR64. Mol Genet Genomics. 2012, 287: 389-410. 10.1007/s00438-012-0686-8.
Bandara PKGSS, Takahashi K, Sato M, Matsuura H, Nabeta K: Cloning and functional analysis of an allene oxide synthase in Physcomitrella patens. Biosci Biotechnol Biochem. 2009, 73: 2356-2359. 10.1271/bbb.90457.
Hashimoto T, Takahashi K, Sato M, Bandara PKGSS, Nabeta K: Cloning and characterization of an allene oxide cyclase, PpAOC3, in Physcomitrella patens. Plant Growth Regul. 2011, 65: 239-245. 10.1007/s10725-011-9592-z.
Anterola A, Göbel C, Hornung E, Sellhorn G, Feussner I, Grimes H: Physcomitrella patens has lipoxygenases for both eicosanoid and octadecanoid pathways. Phytochemistry. 2009, 70: 40-52. 10.1016/j.phytochem.2008.11.012.
Christiansen MW, Holm PB, Gregersen PL: Characterization of barley (Hordeum vulgare L.) NAC transcription factors suggests conserved functions compared to both monocots and dicots. BMC Res Notes. 2011, 4: 302. 10.1186/1756-0500-4-302.
Chomczynski P, Sacchi N: Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal Biochem. 1987, 162: 156-159.
Thompson JD, Higgins DG, Gibson TJ: CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position specific gap penalties and weight matrix choice. Nucleic Acids Res. 1994, 22: 4673-4680. 10.1093/nar/22.22.4673.
Drummond AJ, Ashton B, Buxton S, Cheung M, Cooper A, Duran C, Field M, Heled J, Kearse M, Markowitz S, Moir R, Stones-Havas S, Sturrock S, Thierer T, Wilson A: Geneious v5.4. 2011, Available from http://www.geneious.com/
This work was funded by the Deutsche Forschungsgemeinschaft (DFG) in the framework of the priority program FOR 666.
The authors declare that they have no competing interests.
AMV, HBD and LMV have conceptualized the research. SM and HBD have generated, isolated and characterized the mutants used in this study and performed the microarray analysis. AMV, SM, HBD and LMV have interpreted the microarray results. AMV has performed the experiments that have not yet been mentioned. AMV and LMV have interpreted the latter results and have written the manuscript. All authors read and approved the final manuscript.
Electronic supplementary material
Additional file 2: Figure S1: Domain architecture of maize NAC proteins. A multiple alignment of the consensus sequences of the whole length NAC proteins from each clade was compiled using ClustalW 2.0. Amino acid residues present in at least 50% of the subclade members are displayed in the consensus sequences. (DOCX 865 KB)
Additional file 3: Table S2: A list of motifs detected within the 116 NAC proteins. The protein sequences were screened with MEME (Multiple Em for Motif Elicitation, http://meme.nbcr.net/meme/cgi-bin/meme.cgi ) at a cut off p-value of e-10. The motif location is given as follows: C-/N-term. – C-/N- terminus, NAC – NAC domain, sd. A-E – subdomain A-E. (DOCX 633 KB)
Authors’ original submitted files for images
Below are the links to the authors’ original submitted files for images.
About this article
Cite this article
Voitsik, AM., Muench, S., Deising, H.B. et al. Two recently duplicated maize NAC transcription factor paralogs are induced in response to Colletotrichum graminicola infection. BMC Plant Biol 13, 85 (2013). https://0-doi-org.brum.beds.ac.uk/10.1186/1471-2229-13-85
- NAC transcription factor
- Colletotrichum graminicola
- Biotic stress response
- NAC domain
- DNA binding element