Skip to main content
Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Spatio-Temporal Expression Patterns of Arabidopsis thaliana and Medicago truncatula Defensin-Like Genes

  • Mesfin Tesfaye ,

    Contributed equally to this work with: Mesfin Tesfaye, Kevin AT. Silverstein

    Current address: Capella University, Minneapolis, Minnesota, United States of America

    Affiliation Department of Plant Biology, University of Minnesota, Saint Paul, Minnesota, United States of America

  • Kevin AT. Silverstein ,

    Contributed equally to this work with: Mesfin Tesfaye, Kevin AT. Silverstein

    Current address: Supercomputing Institute for Advanced Computational Research, University of Minnesota, Minneapolis, Minnesota, United States of America

    Affiliation Department of Plant Biology, University of Minnesota, Saint Paul, Minnesota, United States of America

  • Sumitha Nallu,

    Current address: Department of Ecology and Evolution, The University of Chicago, Chicago, Illinois, United States of America

    Affiliation Department of Plant Biology, University of Minnesota, Saint Paul, Minnesota, United States of America

  • Lin Wang,

    Current address: Enterprise Institute for Renewable Fuels, Donald Danforth Plant Science Center, Saint Louis, Missouri, United States of America

    Affiliation Department of Plant Biology, University of Minnesota, Saint Paul, Minnesota, United States of America

  • Christopher J. Botanga,

    Affiliation Department of Biological Sciences, Chicago State University, Chicago, Illinois, United States of America

  • S. Karen Gomez,

    Affiliation Boyce Thompson Institute for Plant Research, Ithaca, New York, United States of America

  • Liliana M. Costa,

    Affiliations Department of Plant Sciences, University of Oxford, Oxford, United Kingdom, School of Life Sciences, University of Warwick, Coventry, United Kingdom

  • Maria J. Harrison,

    Affiliation Boyce Thompson Institute for Plant Research, Ithaca, New York, United States of America

  • Deborah A. Samac ,

    dasamac@umn.edu

    Affiliation US Department of Agriculture-Agricultural Research Service-Plant Science Research Unit, Saint Paul, Minnesota, United States of America

  • Jane Glazebrook,

    Affiliation Department of Plant Biology, University of Minnesota, Saint Paul, Minnesota, United States of America

  • Fumiaki Katagiri,

    Affiliation Department of Plant Biology, University of Minnesota, Saint Paul, Minnesota, United States of America

  • Jose F. Gutierrez-Marcos,

    Affiliation School of Life Sciences, University of Warwick, Coventry, United Kingdom

  • Kathryn A. VandenBosch

    Current address: College of Agricultural and Life Sciences, University of Wisconsin, Madison, Wisconsin, United States of America

    Affiliation Department of Plant Biology, University of Minnesota, Saint Paul, Minnesota, United States of America

Abstract

Plant genomes contain several hundred defensin-like (DEFL) genes that encode short cysteine-rich proteins resembling defensins, which are well known antimicrobial polypeptides. Little is known about the expression patterns or functions of many DEFLs because most were discovered recently and hence are not well represented on standard microarrays. We designed a custom Affymetrix chip consisting of probe sets for 317 and 684 DEFLs from Arabidopsis thaliana and Medicago truncatula, respectively for cataloging DEFL expression in a variety of plant organs at different developmental stages and during symbiotic and pathogenic associations. The microarray analysis provided evidence for the transcription of 71% and 90% of the DEFLs identified in Arabidopsis and Medicago, respectively, including many of the recently annotated DEFL genes that previously lacked expression information. Both model plants contain a subset of DEFLs specifically expressed in seeds or fruits. A few DEFLs, including some plant defensins, were significantly up-regulated in Arabidopsis leaves inoculated with Alternaria brassicicola or Pseudomonas syringae pathogens. Among these, some were dependent on jasmonic acid signaling or were associated with specific types of immune responses. There were notable differences in DEFL gene expression patterns between Arabidopsis and Medicago, as the majority of Arabidopsis DEFLs were expressed in inflorescences, while only a few exhibited root-enhanced expression. By contrast, Medicago DEFLs were most prominently expressed in nitrogen-fixing root nodules. Thus, our data document salient differences in DEFL temporal and spatial expression between Arabidopsis and Medicago, suggesting distinct signaling routes and distinct roles for these proteins in the two plant species.

Introduction

Defensins are a large family of endogenous antimicrobial polypeptides present in most eukaryotic life forms [1], [2]. These small, charged, cysteine-rich polypeptides are secreted or sequestered within compartments of the endomembrane system and have broad-spectrum anti-fungal, anti-bacterial, anti-viral, and/or insecticidal activity via a variety of proposed molecular mechanisms [1], [3], [4], [5], [6].

Plants have a large repertoire of genes encoding defensin-like (DEFL) polypeptides that have a conserved pattern of cysteine residues, but are otherwise highly variable in the mature protein [7], [8], [9]. The model legume Medicago truncatula (hereafter called Medicago) has at least 778 DEFL genes [7], [8], [10], [11], [12]. Arabidopsis has 317 DEFL genes [9] while rice has 93 DEFL genes [8].

DEFL gene families appear to have expanded and diversified in plant genomes via tandem and ectopic duplication followed by successive rounds of diversifying selection [7], [9], [13]. Based on sequence diversity, the DEFLs have been classified into more than 100 different subgroups [8]. The expansion and diversification of the DEFL family appear to have resulted in some divergent subgroups of DEFLs characteristic of different plant lineages, while other subgroups such as the defensins themselves have remained broadly conserved among lineages [8].

The phylogenetic diversity among DEFLs suggests that different gene family members may play distinct roles in divergent taxa, but knowledge of the functions of this large gene family is largely unknown. In contrast, a number of roles for plant defensins have been identified. Some are constitutively expressed or developmentally regulated and act as antimicrobial agents that protect nutrient-rich and vulnerable tissues in seed development and seedling growth [3], [14]. Other defensins are deployed specifically during defense responses and are induced downstream of jasmonate or other defense signaling molecules [15], [16]. Roles for DEFLs in plant-microbe interactions are likely to be varied. For example, nodule cysteine-rich proteins (NCRs) belonging to the DEFL family were recently demonstrated to effect the terminal differentiation of nitrogen-fixing bacteroids in root nodules of certain legumes [17].

Some members of the highly diverse DEFL group have been shown to function in plant development [18]. For example, some S-locus cysteine-rich proteins (SCRs), which make up a subgroup of DEFLs, are expressed in pollen tubes and act as signal molecules in self-incompatibility in some dicots [19], [20]. Other DEFLs have been identified that mediate pollen tube development and guidance [21], [22]. Published evidence suggests that DEFLs act in a variety of plant development processes [6], [23], [24], [25], [26]. However, classifying DEFLs as functioning either in microbial interactions or in plant developmental regulation may be misleading. A tomato defensin shows evidence of bifunctionality, acting both to regulate plant development and to confer disease resistance [27].

Despite great progress towards creating gene expression atlases for Arabidopsis [28] and Medicago [29], gene expression data for DEFLs are far from comprehensive in either species. This is because standard Affymetrix arrays utilized to construct gene atlas projects contain only 12% (Arabidopsis ATH1 array) and 50% (Medicago genome array) of known DEFLs (Silverstein, unpublished). Although deep transcriptome sequencing via RNA-seq methodologies have become routine for expression profiling, the highly redundant nature of the DEFL gene family poses serious problems for mapping short sequence reads. Hence, it has been difficult to ascertain comprehensive expression patterns of DEFLs as a family and to determine whether DEFL functions are conserved or divergent among angiosperms.

To address this gap, we designed a custom Affymetrix microarray (here after called the AtMtDEFL array) with probe sets for known and predicted Arabidopsis and Medicago DEFLs and the closely-related family of maternally expressed genes (MEGs) [8], [30]. The custom array was utilized for hybridizations of mRNAs from a wide range of conditions and tissues from both plant species, enabling a comparative cataloging of DEFL gene expression in the two model plant species. The custom chip analysis of DEFL transcript abundance provided the first expression evidence for many of the computationally identified DEFLs previously lacking gene expression evidence, defined both common and unique patterns of DEFL gene expression between Arabidopsis and Medicago, and identified organ-specific and microbe-induced family members.

Results

Development of the Custom AtMtDEFL Array and Robust Data Normalization Methods

The AtMtDEFL array includes probe sets for 317 Arabidopsis DEFLs, 15 Arabidopsis DEFL-related Genes (MEGs) [8], [30], and 684 Medicago DEFLs [8], plus additional marker genes and probe sets with invariant levels of expression (hereafter called invariant genes) to aid microarray data normalization (See Materials and Methods for details). Probe sets were interspersed on the custom array although chip hybridization and microarray data analysis were performed for only one plant species at a time. The subset of the AtMtDEFL array made up of Arabidopsis probe sets is hereafter referred to as the AtDEFL array whereas the subset of the AtMtDEFL array made up of Medicago probe sets is hereafter termed the MtDEFL array.

Microarray data normalization algorithms such as Affymetrix's MAS 5.0 [31] or loess [32] require that the majority of genes show an unchanged pattern of expression among the conditions under consideration or at least that an equivalent proportion of genes are up- and down-regulated. Alternatively, RMA and other quantile normalization based schemes [33], [34] require that the density distribution of intensities is at least qualitatively similar across samples. These essential probe intensity distribution assumptions for microarray data are clearly violated when analyzing data from boutique arrays such as the AtMtDEFL chip used in this study. For example, we observed more than 500 Medicago DEFLs expressed in nitrogen-fixing root nodules, yet only a minority was detectable in uninoculated roots. These extreme expression patterns pose a challenge to routine microarray data normalization algorithms [35], [36]. In this study, we evaluated three microarray normalization algorithms: the Stable-Based Quantile (SBQ; [36]), RMA with Invariant Median Scaling (RIMS), and RMA with Median Absent Probe set Scaling (RMAPS) (See Materials and Methods, Text S1, and Figures S5, S6, S7, S8, S9, S10, S11 for details). The Stable-Based Quantile (SBQ) approach gave the best performance for the custom chip and despite being restricted to the very small set of genes on the AtMtDEFL array exhibited very tight correlation with full-scale RMA normalization data that utilizes a genome-wide set of genes (Figures 1 and 2, Figure S1). Consequently, we used SBQ to normalize AtMtDEFL custom array datasets in the subsequent studies.

thumbnail
Figure 1. Scatter plots of SBQ normalized gene expression values compared to whole-array RMA across 36 ATH1 arrays.

Only a subset of 299 probe sets that correspond to genes represented on the AtMtDEFL array (37 DEFLs, 171 invariants, 91 marker genes) were used for SBQ normalizations. Each was compared to the reference RMA normalization, which included all 22,810 probe sets on the Affymetrix ATH1 array in the normalization process. Expression values were log2 transformed. All 37 probe sets on the ATH1 array that matched an Arabidopsis DEFL with at least 6 of 11 exact-match probes per probe set were included in the analysis. GEO accessions for ATH1 arrays included three biological replicates of: GSE1491 (seedlings), GSE5630 (cotyledons, leaves, senescent leaves), GSE5631 (roots), GSE5632 (carpels, stage 9 flowers, stamens), GSE5633 (stems), GSE5634 (old and young siliques), and GSE7227 (seeds).

https://doi.org/10.1371/journal.pone.0058992.g001

thumbnail
Figure 2. Scatter plots showing correlation of SBQ normalized AtMtDEFL array expression values compared to publicly available GEO ATH1 array data.

A, roots. B, leaves. C, inflorescences. Probe sets for 171 invariants and 91 marker genes are identical in AtMtDEFL and ATH1 arrays. The 37 DEFL probe sets were represented with different probes on the two arrays with differences in some cases in the underlying gene model. Log2 signals for biological replicates were averaged prior to cross-platform comparison. GEO accessions for ATH1 arrays included: GSM131558, GSM131559, GSM131560 (roots); GSM131498, GSM131499, GSM131500 (leaves); and GSM62694, GSM227612 (inflorescences).

https://doi.org/10.1371/journal.pone.0058992.g002

Validation of Arabidopsis Microarray Data

We employed quantitative reverse-transcription polymerase chain reaction (qRT-PCR) to verify the AtDEFL microarray data. Using geNorm ranking [37], of expression stability of candidate reference genes (details in Materials and Methods) we initially identified four candidates as potential reference genes (Figure S2A). Gene expression stability analysis using qRT-PCR assays showed all four genes to be suitable for transcript quantification (Figure S2B). We selected two of the Arabidopsis genes, metallothionein 2B (At5g02380) and yellow-leaf-specific gene 8 (At5g08290), as reference genes for qRT-PCR validation of microarray data.

We randomly selected 10 Arabidopsis DEFLs as reference points for validation of gene expression patterns (Table S1). Gene expression fold-change values obtained via qRT-PCR were consistent with tissue-specific and/or tissue-enhanced gene expression patterns obtained with the SBQ normalized custom array data. In most cases, fold-changes obtained from microarray data were smaller in amplitude compared with those obtained via qRT-PCR assays.

Many Computationally Predicted Arabidopsis DEFLs Show Constitutive Expression Patterns

Based on MAS5 detection call criteria [31], expression of 234 Arabidopsis DEFLs and MEGs (about 70.5% of the DEFLs and MEGs on the custom chip) was detected in one or more of the tissues examined (Figure 3A). The majority (210) were expressed in reproductive tissues (flowers and mature siliques) with a smaller number (84) expressed in vegetative tissues (roots and leaves) and pathogen-infected leaves (70) (Table 1). Approximately 43 DEFLs were constitutively expressed and detected in all tissues examined (Figure 3A). There were more genes expressed in reproductive tissues than in healthy and pathogen-inoculated vegetative tissues combined (Table 1). We identified DEFLs that were uniquely expressed in only one tissue or condition, the majority of which were unique to reproductive tissues. Arabidopsis DEFLs with tissue-specific expression patterns in this study are listed in Table S2.

thumbnail
Figure 3. Venn diagrams of expressed Arabidopsis DEFLs in different treatments.

A, Number of expressed DEFLs and MEGs in various tissues. B, Comparison of different gene discovery approaches for the number of identified expressed DEFLs by each technique.

https://doi.org/10.1371/journal.pone.0058992.g003

thumbnail
Table 1. Number of Arabidopsis DEFL expression by tissue and condition

https://doi.org/10.1371/journal.pone.0058992.t001

To further improve the information base on the number of Arabidopsis DEFLs for which we have gene expression evidence, we cross-referenced the list of expressed DEFLs in the present study to that of gene lists reported previously by others using sequencing-based transcript profiling approaches: Massively-Parallel Signature Sequences (MPSS) database (http://mpss.udel.edu/at/) and expressed sequence tags (ESTs) in the Arabidopsis Gene Index (AGI) (http://compbio.dfci.harvard.edu/tgi/cgi-bin/tgi/gimain.pl?gudb=arab). The MPSS database is based on sequencing technology that captures very small sequence signature tags (17 bp and 20 bp) for expressed transcripts. The AGI is a culmination of sequencing efforts involving a collection of several hundred thousand ESTs. Combining data from these three approaches there are a total of 268 DEFLs and MEGs with evidence of gene expression in one or more organs and conditions (83% of the 332 DEFLs and MEGs on the custom chip) (Figure 3B). Of this total, the custom chip analysis provided new information on expression of 102 recently identified DEFLs in Arabidopsis that previously lacked evidence for gene expression.

Numerous Arabidopsis DEFLs Show a Predominantly Reproductive Expression Pattern

The SBQ-normalized signal intensity values of DEFLs from a variety of Arabidopsis tissues, including healthy and pathogen-infected tissues presented in Table S2, are schematically displayed as a heat map (Figure 4). From this figure it is apparent that a majority of expressed Arabidopsis DEFLs showed either unique or enhanced expression in inflorescences (representing a pool of floral development stages, with the most mature at anthesis) and mature siliques at stage 17 of plant development [38], [39]. Approximately 30 DEFLs and MEGs were expressed in all Arabidopsis reproductive organs examined. A further 58 DEFLs and MEGs were uniquely expressed in mature siliques.

thumbnail
Figure 4. Transcript profiles of expressed Arabidopsis DEFLs and MEGs.

Treatments were: (1) 7-d-old seedling, (2) 14-d-old seedling, (3) 21-d-old root, (4) inflorescences, (5) siliques, (6) Col-0 Alternaria mock-inoculation, (7) Col-0 Alternaria-inoculated leaf, (8) dde2-2 Alternaria-inoculated leaf, (9) Pseudomonas mock-inoculation at 3 hpi, (10) PtoDC3000 inoculated leaves at 3 hpi, (11) PtoDC3000hrcC- inoculated leaves at 3 hpi, (12) PtoDC3000AvRpt2 inoculated leaves at 3 hpi, (13) Pseudomonas mock-inoculation at 9 hpi, (14) PtoDC3000 inoculated leaves at 9 hpi, (15) PtoDC3000hrcC- inoculated leaves at 9 hpi, and (16) PtoDC3000AvRpt2 inoculated leaves at 9 hpi. The heat map shows median scaling of SBQ normalized signal intensity values as described in Materials and Methods. Colors represent high transcript abundance (magenta), low transcript abundance (green), and average transcript abundance (white).

https://doi.org/10.1371/journal.pone.0058992.g004

SCRs and MEGs were expected to be expressed primarily in reproductive tissues because members of these gene subgroups were known to play regulatory roles in pollen-stigma interactions [40], or in seed development, respectively [26], [41]. Many Arabidopsis SCRs and MEGs are not represented on the Affymetrix ATH1 array. By contrast, our custom array contains probe sets representing 28 SCRs and 15 MEGs. We evaluated the tissue-specific and developmentally regulated expression patterns of these DEFL subgroups using the microarray data collected from several tissues and organs during normal growth conditions and from pathogen-infected tissues. We found that SCRs were expressed primarily in inflorescence tissues, with the exception of one SCR (At1g60989), which showed expression in vegetative tissues that was enhanced in 21-d-old-roots (Figure 5A). Our data also show that eighteen SCRs are uniquely expressed in reproductive tissues (11 uniquely expressed in inflorescences, three in mature siliques, and two in both organs). Most MEGs were expressed uniquely in inflorescences and siliques, although four were expressed in one or more of the tissues examined (Figure 5B). Furthermore, we observed that several previously known plant defensins (PDF2.4, PDF2.6, PDF3.1, PDF3.2) are up-regulated in reproductive tissues (Figure S3A).

thumbnail
Figure 5. Gene expression profiles of Arabidopsis.

A, SCRs. B, MEGs. C, Seeding- and root-specific/enhanced DEFLs. Treatments and heatmap colors are as depicted in Figure 4.

https://doi.org/10.1371/journal.pone.0058992.g005

Arabidopsis DEFL Expression in Vegetative Tissues

Expression of approximately 26% of the DEFLs and MEGs on the custom chip was detected in vegetative tissues, but only five DEFLs were expressed uniquely in these tissues. Interestingly, approximately 14 DEFLs, including an SCR (At1g60989) and a plant defensin (PDF1.5; At1g55010), were predominantly expressed in seedlings and/or roots, in a seedling- and root-specific manner (Figure 5C). Previously known plant defensins PDF2.1, PDF2.2, PDF2.3, and PDF2.5 also showed up-regulated expression in vegetative tissues primarily in seedlings and root tissues (Figure S3A).

We further examined expression patterns of six Arabidopsis genes identified by microarray analysis using the highly sensitive LhG4/OP transactivation system [42]. Genomic regions upstream of the initiation codon were fused to LhG4 and transformed in a pOP::GUS reporter line. We selected six genes for detailed analysis: the SCR expressed in roots (At1g60989), defensin PDF1.2b (At2g26020), which is expressed constitutively and induced in leaves by pathogen infection, and four DEFLs, At5g60553 (expressed in seedlings and siliques), At3g63360 (expressed in seedlings and roots), At4g30074 (expressed constitutively), and At5g05598 (expressed in roots and siliques). Histochemical analysis of 1-week-old T4 transgenic seedlings revealed that the SCR promoter is active in the vascular tissue of roots and cotyledons (Figure 6A). The PDF1.2b promoter is active throughout the seedling with intense GUS staining in hypocotyl tissues (Figure 6B). The hypocotyl and root is also the site of activity of the At5g60553 promoter (Figure 6C). As expected, the promoters of At3g63360 and At5g05598 were active in roots (Figure 6D,F) and the promoter of At4g30074 active throughout the seedling (Figure 6E). These transcriptional fusions confirm our microarray data, revealing that DEFL expression in vegetative and reproductive development is confined to discrete organs and/or cell types.

thumbnail
Figure 6. Transcriptional fusion analysis of Arabidopsis DEFL promoter constructs in T4 transgenic seedlings expressing pSCR:LhG4/OP:GUS.

Histochemical staining for GUS activity in 1-week-old seedlings transformed with promoter constructs of Arabidopsis DEFLs. A, At1g60989. B, At2g26020. C, At5g60553. D, At3g63360. E, At4g30074. F, At5g05598. Scale bar 10 µm.

https://doi.org/10.1371/journal.pone.0058992.g006

Identification of Fungal Pathogen-Responsive Arabidopsis DEFLs

To identify pathogen-responsive DEFLs in Arabidopsis, wild type and dde2-2 mutant plants were challenged with the necrotrophic fungal pathogen Alternaria brassicicola, the causal agent of early blight [43]. DDE2 encodes allene oxide synthase, which is essential for jasmonate (JA) biosynthesis [44]. In agreement with previous findings [43], [45], dde2-2 plants were found to be more susceptible to A. brassicicola than Col-0 (Figure S4). Gene expression profiles of leaf samples collected at 24 h post inoculation (hpi) and those from mock-inoculated plants were compared. A total of 21 genes including eight DEFLs and five PDFs were significantly (P<0.05) differentially expressed (Table S4). Of these, two DEFLs (At3g05730, At2g43550) were significantly repressed 24 hpi with A. brassicicola, regardless of the plant genotype. Transcript abundance of one DEFL (At2g43530) was also significantly reduced by A. brassicicola inoculation in the dde2-2 mutant background compared with Col-0 (Table S4). Differentially regulated genes include known JA-dependent defense response genes such as PDF1.1/PDF1.2, PDF1.2a-c, and PDF1.3 (At1g75830, At5g44420, At2g26020, At5g44430, At2g26010), though the probe sets for the latter three genes are complicated by potential cross-hybridization (i.e., they have ‘_x_at’ suffixes). A hevein-like protein precursor (HEL1; At3g04720) and a gene encoding a basic chitinase (At3g12500) were also differentially expressed. As expected, transcripts corresponding to JA-responsive marker genes did not accumulate to the same extent in the dde2-2 mutant as they did in Col-0. However, three Arabidopsis DEFLs showed strong JA-dependent induction (Table S4).

DEFL Expression Patterns in Arabidopsis Coincide with Bacterial Pathogen Recognition

In order to assess which DEFL genes are expressed during bacterial pathogen responses, we collected leaves challenged with bacterial strains PtoDC3000, PtoDC3000AvrRpt2, or PtoDC3000hrcC- at 3 and 9 hpi. We found that at 3 hpi, 12 DEFLs and six PDFs were significantly (P<0.05) differentially regulated among the three bacterial strains used and the number of significantly (P<0.05) differentially regulated genes increased to 29 DEFLs and eight PDFs at 9 hpi (Table S5). All but two genes that were differentially regulated at 3 hpi were also differentially regulated at 9 hpi. PtoDC3000-induced genes at 9 hpi included 13 DEFLs and six PDFs and PtoDC3000-repressed genes included 16 DEFLs and two PDFs (Table S5).

Two well-studied modes of pathogen recognition mechanisms occur in plants: recognition of molecular patterns (pathogen-associated molecular patterns, PAMPs, or microbe-associated molecular patterns, MAMPs) common to microbes and recognition by host resistance proteins of certain effectors delivered inside plant cells by pathogens. Many effector proteins are known to interfere with host immune signaling. Recognition of PAMPs and type III effectors by host plants leads to induction of PAMP-triggered immunity (PTI) and effector-triggered immunity (ETI), respectively. We expected differences in transcript accumulation of PTI- and ETI-responsive genes in leaves inoculated with PtoDC3000hrcC- (a strain unable to deliver effectors which induce PTI) and PtoDC3000AvrRpt2 (AvrRpt2 is an effector that triggers ETI in Col-0) strains compared to plants inoculated with wild type PtoDC3000. By these criteria, a DEFL (At5g43285), five plant defensins (PDF1.2a-c, PDF1.3, PDF1.4), and several marker genes including a hevein-like protein (HEL/PR-4; At3g04720), and two high-affinity nitrate transporters (At3g45060, At1g08090) could be considered as PTI-responsive genes. Genes that showed evidence of ETI-response expression patterns included two DEFLs (At3g61185, At5g46871), a plant defensin (PDF1.1; At1g75830), as well as genes encoding pathogenesis-related protein 3 (PR-3; At3g12500), PR-1 (At2g14610), 4-coumarate:Coenzyme A ligase (4CL; At3g21230), and a MYB108 transcription factor (At3g06490) (Table S5).

Co-expression Analysis using Known Marker Genes for Defense Signaling Pathways Verified Expression Patterns of Pathogen-Responsive DEFLs

We extended our analysis of the Arabidopsis custom microarray data for co-expression patterns using three marker genes for host defense responses. Genes used for the co-expression analysis include PDF1.2a (At5g44420), which is a marker for host defense via the JA-mediated pathway [46], [47], coronatine-insensitive 1 (COI1; At2g39940), also known to be induced by JA [48], as well as the MAMPs-inducible gene, FLG22-inducible receptor-like kinase 1 (FRK1; At2g19190), which is implicated in early defense signaling associated with the perception of flagellin [49]. Our analysis identified 16 genes, including four DEFLs, that showed co-regulated (R2 ≥ 0.7) expression patterns with FRK1 (Figure S3B). Other co-regulated genes with FRK1 included PR-1 (At2g14610, At1g64280), PR-5 (At1g75040), ascorbate peroxidase (At1g07890), β-glucanase (At3g57260), and glycerol kinase (At1g80460). We identified two DEFLs (At2g16367, At5g18407) and four PDFs (At1g19610, At2g26010, At2g26020, At5g44430) that had co-regulated (R2 ≥ 0.7) expression patterns with PDF1.2a and/or COI1 (Figure S3C). Except for At2g16367, transcript abundance of the remaining co-regulated DEFLs and other genes was significantly regulated by Pseudomonas and/or A. brassicicola inoculation (Tables S4 and S5).

Medicago DEFLs Show Tissue- and Condition-Specific Gene Expression Patterns

Expression profiles of 684 Medicago DEFLs were surveyed in M. truncatula accession A17 using the MtDEFL custom chip. We profiled different plant organs as well as various tissues inoculated with plant pathogens and symbiotic microbes. The SBQ-normalized signal intensity values presented in Table S3 are schematically displayed as a heatmap in Figure 7. The most prominent gene expression patterns were very strong gene expression in either root nodules or in seeds.

thumbnail
Figure 7. Transcript profiles of expressed Medicago DEFLs.

Treatments were: (1) Germinating seed, (2) stem, (3) flower buds, (4) flowers, (5) seed, (6) uninoculated root for mycorrhizal control, (7) mycorrhizal root, (8) uninoculated root for nodule control, (9) nodules at 14 dpi, (10) P. medicaginis mock-inoculated root, (11) P. medicaginis-inoculated root, (12) C. trifolii mock-inoculated leaf, and (13) C. trifolii-inoculated leaf. The heat map shows median scaling of SBQ normalized signal intensity values as described in materials and methods and colors represent high transcript abundance as depicted in Figure 4.

https://doi.org/10.1371/journal.pone.0058992.g007

Based on MAS5 gene expression detection criteria [31], a total of 176 Medicago DEFLs (26% of the Medicago DEFLs on the custom chip) were expressed in one or more of the following Medicago tissues that were grown under normal conditions (i.e. not inoculated with microbes): germinating seeds, leaves, stems, flower buds, open flowers, immature seeds, and roots (Figure 8A). In vegetative tissues 95 DEFLs were expressed and 123 DEFLs were expressed in reproductive tissues (Figure 8A). Approximately 31 DEFLs were expressed in all vegetative, reproductive, and microbe-inoculated tissues (Figure 8A). Approximately 79% of the total DEFLs on the custom chip were expressed in microbe-inoculated tissues (Figure 8A, B).

thumbnail
Figure 8. Venn diagrams of Medicago DEFLs expressed in different treatments.

A, Comparison among all tissue types. B, Tissues inoculated with microbial symbionts and plant pathogens. C, Reproductive tissues.

https://doi.org/10.1371/journal.pone.0058992.g008

Among Medicago DEFLs expressed in reproductive stages, only MtgAC142396_38300, MtgCU302334_101329, MtgAC149130_78022, and MtgAC147712_80528 were uniquely expressed in flower buds and/or flowers. In contrast, 52 DEFLs were uniquely expressed in developing Medicago seeds (Figure 8C). Medicago DEFLs with tissue-specific expression patterns in this study are listed in Table S3.

Expression of Medicago DEFLs in Symbiotic Tissues

Medicago DEFL expression during symbiotic interactions of M. truncatula A17 was evaluated using the widely studied arbuscular mycorrhizal (AM) fungus Glomus intraradices and the root nodule forming soil bacterium Sinorhizobium meliloti strain Sm1021. For AM symbiosis, G. intraradices-colonized roots (Myc+) were collected at 28 days post-inoculation (dpi), which is a heavily infected stage. Approximately 44 Medicago DEFLs were expressed in Myc+ roots. For statistical analysis of gene expression during AM symbiosis, signal intensity values in Myc+ colonized roots were compared with signal intensity values with non-mycorrhizal control roots (Myc−). Eleven DEFLs were significantly up-regulated (P<0.05), whereas one Medicago DEFL was significantly down-regulated (P<0.05) in Myc+ roots compared to Myc- roots (Table S6).

The majority (77%) of the DEFLs on the custom chip were found to be expressed in root nodules formed by S. meliloti at 14 dpi. Statistical analysis of SBQ normalized data revealed that 515 Medicago DEFLs were significantly up-regulated (P<0.05) in nitrogen-fixing root nodules compared to uninoculated root controls of similar age (Table S7). Only two Medicago DEFLs (MtgCR3171614, MtTC94214) were significantly down-regulated (P<0.05) in 14 dpi nodules compared to uninoculated roots of similar age (Table S7).

Medicago DEFL Expression During Pathogenic Interactions

We investigated DEFL expression patterns during interactions of Medicago plants with a foliar pathogen, Colletotrichum trifolii, and a root pathogen, Phytophthora medicaginis. Medicago truncatula accession A17 is resistant to C. trifolii and displays a rapid hypersensitive response (HR) at 12 to 24 hpi [50]. To identify DEFLs whose expression is coincident with the HR, the MtDEFL chip was used to evaluate gene expression patterns in M. truncatula A17 at 24 hpi with C. trifolii. Approximately 36 DEFLs were expressed in C. trifolii inoculated leaf samples. Statistical analysis showed that four DEFLs were significantly down-regulated (P<0.05) in C. trifolii inoculated leaf samples compared to mock-inoculated leaf (Table S8).

The accession A17 is moderately susceptible to P. medicaginis with lesions being typically small and occurring about 5 dpi [51]. Our preliminary study using qRT-PCR detected the highest significant differential expression of two antimicrobial genes (thaumatin-like protein and PR10) occurred at 4 dpi with P. medicaginis. Expression analysis using the MtDEFL array revealed that approximately 41 DEFLs were expressed in infected root segments of Medicago in response to P. medicaginis, whereas only eight DEFLs were significantly up-regulated (P<0.05) in Phytophthora-challenged roots compared to mock-inoculated root tissues of similar age at 4 dpi (Table S9).

Discussion

A Small Set of DEFLs are Pathogen-Responsive in Arabidopsis and Medicago

DEFLs generally share common features in gene structure and genomic organization to defensins, which make up one subfamily within the DEFL superfamily [7], [8], [9]. It is expected that DEFLs that possess antimicrobial activity are likely to be up-regulated in response to pathogens. Thus, to identify additional DEFLs with possible antimicrobial activity, we profiled DEFL expression in Arabidopsis plants infected with bacterial or fungal pathogens as well as in infected Medicago roots and leaves. Through expression profiling and co-expression analysis with known marker genes for early defense signaling and JA-mediated host response, we identified several pathogen-responsive Arabidopsis DEFLs. In contrast, few DEFLs were expressed in Medicago roots infected with P. medicaginis or in leaves exhibiting an HR in response to C. trifolii. These genes comprise a subset of DEFLs that warrant further investigation into their antimicrobial activity and role in plant defense.

Plants activate numerous defense responses upon recognition of invading pathogens. Several plant defensins with demonstrated protease inhibitor or antimicrobial activity are induced by pathogens via the JA signaling pathway [4], [46], [47]. Of the 15 plant defensins previously described, we found that PDF1.1, PDF1.2a-c, PDF1.3, and PDF1.4 were induced by pathogens and showed co-regulated expression patterns with known marker genes in pathogen-infected leaves. Transcript abundance of PDF2.1, PDF2.2, PDF2.3, and PDF2.5 were down-regulated by pathogen infection, but showed higher transcript abundance in seedlings, roots, and inflorescence tissues. The expression profiles of these plant defensins were consistent with previous reports that showed up-regulated expression of PDF1.2 and down-regulated expression of PDF2.2 by infection with A. brassicicola [4].

Resistance against necrotrophic pathogens such as A. brassicicola requires JA-mediated signaling, leading to activation of defenses including defensins [43], [45]. Results of experiments using A. brassicicola infections of the dde2-2 mutant, with impaired JA synthesis and increased susceptibility to A. brassicicola, are highly suggestive that expression of some DEFLs are induced via JA-mediated signaling. Co-expression of these genes with known JA-signaling marker genes (PDF1.2a, COI1) used in our analysis suggested that a few of the novel DEFLs are involved in plant defense and their expression is likely mediated by the JA-signaling defense pathway.

Complex transcriptional reprogramming involving a large number of genes has been shown to be involved during PTI and ETI. Gram-negative bacterial pathogens such as the hemibiotroph PtoDC3000 employ the type III secretion system to translocate effector proteins into the host cytoplasm. The bacterial HrcC protein is an essential component of the type III secretion system, so bacteria with the hrcC mutation cannot deliver type III effectors into the host cytoplasm. Therefore, the strain PtoDC3000hrcC- can induce PTI but cannot interfere with PTI, whereas the wild type PtoDC3000 induces and interferes with PTI. Consequently, PtoDC3000 reproduces well in Col-0 but PtoDC3000hrcC- cannot. On the other hand, the strain PtoDC3000AvrRpt2 induces ETI because Col-0 expresses the resistance protein RPS2, which recognizes AvrRpt2. We used PtoDC3000hrcC- and PtoDC3000AvrRpt2 to characterize DEFL transcriptional responses in Col-0 leaves during PTI and ETI, respectively. In total, we identified 39 Arabidopsis DEFLs (Table S4) that were differentially regulated in response to P. syringae. We also found that considerably more DEFLs were expressed at 9 hpi compared to either 3 hpi with P. syringae or 24 hpi with A. brassicicola (37 DEFLs compared to three DEFLs and 13 DEFLs, respectively). Our data suggest that several DEFLs may be important in PTI and/or ETI. Furthermore, co-expression analysis using the PAMPs-induced marker gene, FRK1, suggested that the expression of up to nine DEFLs may be related to early defense signaling in response to P. syringae.

Putative Roles for DEFLs in Reproduction and Symbiotic Microbial Associations

More than 100 DEFLs are specifically expressed in Arabidopsis inflorescences and/or siliques while approximately 60 DEFLs are expressed in reproductive tissues in Medicago, most of which (56 DEFLs) are expressed only in seeds. The results in Arabidopsis were consistent with earlier observations of gene expression patterns of some known DEFLs [8], [52], [53] that were expressed solely in siliques [52] or ovules [53] and detected via MPSS or whole-genome tiling arrays. The specific expression of Arabidopsis DEFLs in synergids, which were found to be important in the origin of pollen tube attractant, suggest that some of those Arabidopisis DEFLs are likely to be involved in different aspects of fertilization [54]. Medicago DEFL expression patterns in this study were consistent with previously observed patterns of gene expression in several EST libraries and defensin gene expression in situ [55], [56]. In particular, we observed that MtDef1.1, MtDef2.1, and MtDef4.6 were expressed at high levels in seeds and MtDef4.2 showed high constitutive expression in all tissues examined. A few of the Medicago defensins including the probe sets MtTC101060_x_at, MtTC104515_at, MtAL385826_s_at, MtTC105086_at, and MtTC98064_at were found to be the most significantly expressed genes in response to G. intraradices root colonization. Previously, TC77480, corresponding to MtTC101060_x_at in the custom chip, was reported to be strongly expressed in M. truncatula roots at 2 to 4 weeks post-inoculation with G. versiforme [55]. The recent report that over-expression of MtDef4.2 in transgenic Arabidopsis results in enhanced disease resistance [56] suggests that some Medicago DEFLs play a role in plant defense.

DEFLs have a variety of properties that make them ideal molecular signals, especially in regulatory control of fertilization. They exist in large tandemly duplicated gene families with high birth and death rates that include numerous pseudogenes [9]. Thus, new genes with novel specificities can be created quickly via gene conversion events. Additionally, they are highly polymorphic and rapidly evolving [9], [19], [57]. DEFLs have been co-opted for the purpose of preventing self-pollination in the Brassicaceae [58] in which the defensin-like SP11 (also known as SCR) was shown to bind to the S-locus receptor kinase to initiate a cascade of events leading to self-pollen rejection. In Torenia fournieri, a pair of DEFLs was shown to serve as the elusive molecular signal exuded from the female gametophyte that attracts pollen tubes to the embryo sac [21]. DEFLs have also been co-opted to erect species barriers in animals [59].

From MtDEFL array analysis and previous in silico analysis of Medicago ESTs it was observed that a large number of Medicago DEFLs are expressed almost exclusively in nitrogen-fixing nodules [7], [11]. A recently published report regarding a few DEFLs found in nodules (called nodule-specific cysteine-rich peptides in that study) indicated that nodule DEFL peptides similar to some defensins triggered membrane modifications and inhibited cytokinesis in bacteria [17]. In addition, ectopic expression of selected nodule-specific cysteine-rich peptides in Lotus japonicus, a legume that lacks DEFL peptides, triggered terminal differentiation of Rhizobium loti in nodules. Based on these findings and additional reports of fungal hyphal branching on application of defensin peptides [60], it is possible that the DEFLs might induce similar changes in mycorrhizal hyphae. To further characterize the nodule DEFLs, we have performed in-depth examinations of the expression patterns of nodule DEFLs, using different symbiotic bacterial mutants and developmentally arrested nodules (Nallu et al., unpublished).

Conclusion

Here we show that a custom microarray analysis provides a rich source of information on the expression patterns of the large family of DEFLs in two model plant systems for which expression data was lacking. Our study revealed distinct temporal and spatial DEFL expression in Arabidopsis and Medicago plants. We cataloged DEFLs that are constitutively expressed and DEFLs that are expressed uniquely in reproductive tissues, seeds, seedlings, roots, or leaves. A small group of DEFLs was identified that are uniquely induced in response to pathogens. The patterns of gene expression revealed notable differences in DEFL expression specificity in the two species. Arabidopsis and Medicago are sister clades within the dicot subclass Rosidae. Medicago belongs to the Fabaceae, or legume family, and its genome lacks extensive macrosynteny with Arabidopsis [61]. The custom microarray results reveal that most Arabidopsis DEFLs are expressed in reproductive tissues, whereas in Medicago the majority of DEFLs are expressed in nitrogen-fixing nodules. The large number of DEFLs expressed in seeds is the commonality across the two plant species. These results raise an intriguing question about the evolution of DEFLs in dicots and their diverse functions. One of the possible functions of Arabidopsis DEFLs in inflorescences might be to prevent self-pollination and/or cross-species hybridizations. On the other hand, the rapid expansion of DEFLs in Medicago exclusively expressed in root nodules is indicative of extensive selection to support the biological process of nitrogen fixation. Further functional analysis on the DEFL subfamilies found in Arabidopsis and Medicago will aid our understanding their diverse functional roles of DEFLs in plants. In addition, comparative genomic studies will add a new perspective on the evolution of this prolific and highly variable gene family among flowering plants.

Materials and Methods

AtMtDEFL Array Design Features and Description

The AtMtDEFL array was commissioned from Affymetrix (Santa Clara, CA) and includes one probe set each for 317 Arabidopsis DEFLs and 15 DEFL-related MEG family members [8], [30]. It also includes 684 probe sets (some probe sets exactly matched an entire subfamily of related DEFLs) representing all 756 Medicago DEFLs that were previously identified [8]. The custom chip also includes probe sets of 31 Arabidopsis genes to serve as markers for expression in particular morphological structures and/or biological processes (e.g., PR-1 through PR-5, ABI1, EIN2, seed- and floral-specific genes). There were also 23 Medicago probe sets that were expected to be specific to seeds, other morphological structures, or to pathogen induction, based on the MtDB2 query interface [62]. In addition, the custom chip included 171 probe sets directly from the Arabidopsis ATH1 array (Affymetrix), which we have designated as ‘invariant genes’. These probe sets were chosen because they had a coefficient of variation (CV) of less than 10% across a collection of more than 5,000 AtGeneExpress array hybridizations (http://arabidopsis.org/info/expression/ATGenExpress.jsp).

Similarly, 172 invariant probe sets were taken directly from the Affymetrix Medicago Genome Array, because they showed less than 10% CV across more than 100 GeneChip hybridizations [63]. Beyond these core invariants, 60 Arabidopsis probe sets were also included that had a CV of less than 3% across select tissue subsets. However, 20 Medicago invariant probe sets, chosen based on the sparse set of experimental conditions available at the time of custom chip design, failed the 10% CV threshold, when their expression profiles were re-analyzed against the 100 Medicago hybridizations available after the custom chip was produced. Probe sets for marker genes and invariant genes were designed exactly as they appeared on the standard ATH1 and Medicago Genome arrays.

Probe sets from the two species are interspersed on the array although separate chip description files (cdfs) were created at Affymetrix with the intent that hybridization and analysis of the array would be performed using only one species at a time. All probe sets were represented by 11 perfect match and 11 single mismatch probes, as was typical of Affymetrix array designs. As with all Affymetrix designs, a probe set is given an ‘_x_at’ suffix to indicate that one or more probes within the probe set cross-hybridizes to an unintended target and an ‘_s_at’ suffix is used to indicate that all 11 probes in the probe set exactly match two or three gene family members. In general, expression values for cross-hybridizing probe sets (i.e., those with ‘_x_at’ suffixes) from Arabidopsis should be interpreted with caution. For Medicago, the ‘_s_at’ and ‘_x_at’ suffixes ascribed to probe sets at the time of array design are misleading because at that time, the Medicago genome was unassembled and consisted of highly redundant, partially assembled BAC sequences. We have remapped all probes to the current release (Mt3.5v5) of the genome annotation (see Text S1, Tables S10 and S11) and determined that only 11% of Medicago probe sets cross-hybridize to unintended genes and only 7% exactly match two or three gene family members.

Arabidopsis Plant Material and Growth Conditions

Col-0 and dde2-2 (At5g42650) in the Col-0 background [44] were used in this study. Seeds were imbibed and stored at 4°C for 3 d before planting in an appropriate growth medium. Arabidopsis plants used for harvesting inflorescences (-2 to 0 d post-anthesis), siliques at stage 17 of plant development [38], [39], and pathogen-inoculated leaves were grown in SUNGRO sunshine potting mix (SUNGRO Horticulture, Pine Bluff, AZ). For harvesting root tissues, Arabidopsis plants were grown in vermiculite (SUNGRO Horticulture). Seeds for seedling tissue harvest were sterilized by treating with 10% (v/v) bleach for 20 min, rinsed in sterile water several times and kept at 4°C for 3 d before planting on rectangular plastic plates containing 1x Murashige and Skoog (MS) salt mixture supplemented with 1% sucrose in 1% agar. Plates were kept vertical in a growth chamber and seedlings were collected 7 and 14 d after sowing. All Arabidopsis experiments were conducted in growth chambers set at a light intensity of approximately 170 µmol m−2 s−1, temperature of 22°C, and a 12-h photoperiod. Plants were watered with tap water as needed. Three biological replicates were produced for each treatment.

Pathogen Infection of Arabidopsis Plants

A. brassicicola strain ATCC96866 was cultured on 0.5X potato dextrose agar at 22°C. Spores were harvested from 10-d-old cultures by washing with water and filtering through four layers of cheesecloth. Spore concentrations were determined using a hemocytometer. For pathogen challenge, leaves of 21-d-old Arabidopsis plants were inoculated with A. brassicicola spores according to Nafisi et al. [64]. Briefly, the third, fourth, and fifth true leaves of each plant were inoculated for monitoring disease symptoms as well as for microarray analysis of DEFL expression. The three inoculated leaves from each plant were collected and bulked for RNA isolation. The mock-inoculated plants were treated in a similar manner with sterile water containing 0.02% Tween-20 used as inoculum. Leaf samples were collected 24 h after inoculation and were immediately frozen in liquid nitrogen for storage at−80°C until needed for total RNA extraction.

For experiments with bacterial pathogens, virulent P. syringae pv. tomato DC3000 (PtoDC3000), a derivative of PtoDC3000 lacking hrcC (Pto DC3000hrcC-), and PtoDC3000 carrying AvrRpt2 (PtoDC300AvrRpt2) were cultured as described previously [65], [66], [67]. Four-week-old Arabidopsis plants were inoculated with bacterial strains essentially as described before [67]. Control plants were mock-inoculated with 5 mM MgSO4. Leaves were collected 3 and 9 hpi, immediately frozen in liquid nitrogen, and stored at −80°C until needed for total RNA extraction.

Medicago Plant Culture and Tissue Harvest

Seeds of M. truncatula accession A17 were sterilized and germinated as described previously [68]. Unless indicated otherwise, Medicago plants were grown from 24 h germinated seedlings transplanted into six-inch pots containing an equal mixture of Turface (Profile Products LLC, Buffalo Grove, IL) and Metro Mix (SUNGRO - 200 series) and fertilized with Osmocote PLUS (15-9-12). All Medicago experiments were conducted in controlled growth chambers with a 16 h photoperiod, 200 to 300 µmol m−2 s−1 light intensity, 50% relative humidity, and 25°C and 21°C day- and night-time temperatures, respectively. All Medicago tissues and organs were collected from three biological replicates, with samples collected and pooled from multiple plants in each replicate. Plant samples were immediately frozen in liquid nitrogen during harvest and were stored at −80°C for subsequent RNA extraction.

Medicago flower buds that were 6 to 8 mm (measured from the base of the bud excluding the petiole to the tip of the sepals), tightly closed, and whose petals had not emerged beyond the sepals were collected from 80-d-old plants. Closed flowers (with petals bigger than the sepals) and open flowers were harvested from 80-d-old plants and pooled. For seed samples, flowers were tagged at anthesis as described by Wang and Grusak [69] and a pool of seeds were collected 10 to 21 d after pollination from 98-d-old plants. Seedlings with radicles 8 to 12 mm long were collected at 24 h post-germination. Stem segments consisting of the fifth and sixth internodes from the shoot apex were collected from 8-week-old Medicago plants as described previously [70].

To obtain nodule tissues, plants were grown on buffered nodulation medium [71], pH 6.5, with 1.2% plant tissue culture grade agar (Sigma-Aldrich, St. Louis, MO) in 245 mm×245 mm plates (Corning, Lowell, MA, USA). The radicles of sterile germinated seeds were placed on a moist, sterile germination paper on top of the agar medium and plates were wrapped with a sterile black cotton cloth (Cotton Club Black, #074300603820, Wal-Mart). Plates were maintained vertically in a growth chamber as described above. At 5 d after planting, plants were inoculated with 100 µL/root of a washed suspension of S. meliloti strain Sm1021 [OD600] =  0.05 in sterile water). Control roots were mock inoculated with 100 µL sterile water. At 14 dpi, approximately 5-cm-long nodule-bearing root segments were harvested from inoculated plants. At the same time, roots consisting of approximately 5-cm root segments corresponding to the regions harvested for 14 dpi nodules were collected from mock-inoculated plants. Root tips were removed from all plants at the time of harvest to reduce transcript contribution from root meristematic cells.

For mycorrhizal roots, germinated seedlings were transplanted into Turface (Profile Products LLC) and were grown in growth chambers. Glomus intraradices spores were prepared from plates as previously described [72]. Twenty-one–day-old plants were inoculated with 1,000 G. intraradices spores per plant as described previously [73]. Control plants were mock inoculated with distilled water. At 28 dpi, mycorrhizal roots without the root tip were harvested and immediately frozen in liquid nitrogen. Roots of mock-inoculated plants were similarly harvested. Throughout the experiment, plants were fertilized with 100 mL/pot using half-strength Hoagland's solution with 1x nitrogen, as needed.

For Phytophthora-infected roots, germinated seeds were placed in CYG seed germination pouches (Mega International, West St. Paul, MN), grown, and inoculated as described previously [51]. At 4 dpi, infected hypocotyl and root segments were harvested from both the infected and mock-inoculated plants, frozen immediately in liquid nitrogen, and held at −80°C for subsequent RNA extraction.

For Colletotrichum-infected leaves, 19-d-old plants were sprayed to run-off with a suspension of C. trifolii spores at 106 spores/mL containing 0.05% Tween-20 as described previously [51]. Mock-inoculated plants were sprayed with sterile water containing 0.05% Tween-20. After 24 h, leaves from pathogen-inoculated or mock-inoculated plants were collected, frozen immediately in liquid nitrogen, and held at −80°C for subsequent RNA extraction.

Generation of Arabidopsis Lines Using the LhG4 transactivation System and GUS Histochemical Staining

Genomic regions corresponding to promoter regions upstream of the initiation codon of selected Arabidopsis DEFLs were cloned by PCR using template genomic DNA isolated from rosette leaves and primer sequences (Table S12) that contained attB2 and attB1 sites upstream of the 5′ and 3′ gene-specific priming sequences, respectively. PCR products were cloned into the pGEM T-easy vector following the manufacturer's instructions (Promega, Madison, WI). The resulting plasmid DNA containing promoter fragments was subjected to BP Clonase recombination reaction with pDONR 207 (Invitrogen, Carlsbad, CA) and transformed into E. coli DH5α. Cloned promoter sequences were validated by sequencing. Transcriptional fusion of DEFL promoters were constructed by transferring the cloned promoter regions in front of the chimeric LhG4 [42], and transferred into the pBINPLUS binary vector using standard molecular biology protocols [74]. Binary vectors were mobilized into Agrobacterium tumefaciens strain GV3101. The resulting A. tumefaciens strains were used for floral dip transformation of Arabidopsis plants carrying an pOp:GUS reporter construct for transactivation [75]. Transgenic plants were selected on MS medium supplemented with 50 mg/mL kanamycin. Twenty transformed lines carrying a single copy of the transgene were selected for each construct.

For histochemical analysis, 1-week-old seedlings were vacuum-infiltrated with a staining solution containing 0.5 mM 5-bromo-4-chloro-3-indolyl-β-D-glucuronic acid, 0.15 M NaH2PO4, pH 7, 2 mM K3Fe(CN)6, 2 mM K4Fe(CN)6, and 0.05% Triton X-100. Seedlings were incubated overnight in the staining solution and cleared overnight in 100% ethanol.

RNA Extraction and GeneChip Hybridization

Approximately 150 mg of Arabidopsis or Medicago tissue ground in liquid nitrogen was used for total RNA extraction. Total RNA from Medicago seeds and germinating seedlings was extracted using the Spectrum Plant Total RNA Kit (Sigma-Aldrich) following the manufacturer's instructions. Total RNA from mature Arabidopsis siliques was extracted using the hot phenol total RNA extraction protocol [76]. Total RNA from all other Arabidopsis and Medicago tissues was extracted using TRIZOL reagent (Invitrogen) following the manufacturer’s instructions. During RNA extraction, contaminating genomic DNA was removed by incubating samples with TURBO™ DNase following standard procedures suggested by the supplier (Applied Biosystems, Foster City, CA). The integrity and quality of total RNA was verified using the Agilent 2100 Bioanalyzer RNA 6000 Nano LabChip (Agilent Technologies, Santa Clara, CA). For Arabidopsis siliques, 100 ng total RNA was labeled using a 2-cycle Affy chip labeling protocol for eukaryotic reactions following the manufacturer’s suggested procedures (Affymetrix). For the other Arabidopsis tissues and all Medicago samples, 10 µg of total RNA was used to produce biotin-labeled cRNA using Affymetrix suggested procedures for 1-cycle eukaryotic reactions (Affymetrix). Ten micrograms of biotin-labeled cRNA, fragmented as suggested by Affymetrix, was hybridized to the AtMtDEFL array. The integrity and quality of labeled and fragmented biotin-labeled cRNA was verified using the Agilent 2100 Bioanalyzer RNA 6000 Nano LabChip (Agilent Technologies). GeneChips were hybridized, washed, stained and scanned as previously described [70].

Microarray Data Normalization and Analysis

Microarray normalizations and initial analyses were performed in R using custom scripts that made use of Bioconductor routines [77]. All scripts are available upon request. In addition to RMA [33], three microarray data normalization methods were compared. To implement the Stable-genes Based Quantile (SBQ) normalization [36], we first combined expression data from all 11 probes within a probe set into a single expression measure using the Bioconductor expression command using RMA-style background correction and median polish probe summarization. These summarized values were output from R and used as input to the SBQ perl script [36]. For RMA with Median Absent Probe set Scaling (RMAPS) we performed RMA separately on each group of biological replicates (within which the density distribution assumptions hold) using the RMA routine within the Bioconductor package. We then rescaled the log2 expression levels for each biological replicate group such that the median values among the set of probe sets that had an absent call (MAS5 calls routine in the affy package) across all sampled conditions were equal from one replicate group to the next. For RMA with Invariant Median Scaling (RIMS), we performed RMA separately on each group of biological replicates as above. Then we rescaled the expression levels for each replicate group according to the median value of the set of invariant genes.

We also calculated a detection call (‘present’ vs. ‘absent’) for each probe set using default MAS5 parameters except changing α1 = 0.05 as suggested for 11 probe pairs per probe set by Liu et al. [31]. For statistical analysis, SBQ normalized signal intensity values were log2 transformed and statistical analysis was based on a t-test or ANOVA (P<0.05) with Benjamini and Hochberg false discovery rate multiple testing correction [78], and the corrected p values were designated as q values. To identify DEFLs and marker genes that showed co-expression patterns, Pearson correlation coefficients were calculated for each probe set using the GeneSpring Expression analysis platform version 7.3 (Agilent Technologies). For gene expression data clustering analysis, the average linkage clustering algorithm and the Pearson correlation similarity measure were applied as provided in GeneSpring Expression analysis software version 7.3 (Agilent Technologies). Heat maps were generated with GeneSpring Expression analysis platform as well as the heatmap2 Bioconductor package.

All microarray data in this study have been deposited in the Gene Expression Omnibus under platform number GSE34401 (http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE34401) with two subseries: GSE34398 (expression data of DEFLs from different parts and treatments of Arabidopsis) and GSE34311 (expression data of DEFLs from different parts and treatments of Medicago).

Real-time RT-PCR Assays

We employed quantitative reverse-transcription polymerase chain reaction (qRT-PCR) to validate the DEFL microarray data trends that were collected from several Arabidopsis tissues and pathogen challenged leaves. Initially, we evaluated the expression patterns and detection calls of candidate invariant genes included in the custom chip. Based on the microarray data collected using the AtMtDEFL chip, we selected 10 of the invariant genes for further evaluation of gene expression data stability. Genes were selected to cover a range of signal intensity values. The raw signal intensity values were imported into geNorm software [37] for gene expression stability analysis. Based on their stability score, we then selected four reference genes, metallothionein 2B (At5g02380), yellow-leaf-specific gene 8 (At5g08290), sumo conjugating enzyme 1 (At3g57870), and polyubiquitin (UBQ11), for validation of gene expression stability using qRT-PCR assays. Gene-specific primers (Table S12) were designed using PrimerExpress software (Applied Biosystems). Gene expression stability analysis was performed using the average threshold cycle (Ct) of the four candidate reference genes and the geNorm software. Total RNA extraction procedures were as described above and first-strand cDNA was prepared from 2 µg of total RNA with the Superscript RT II kit (Invitrogen) and oligo dT primers (Sigma-Aldrich) at 200 ng/reaction, according to the manufacturer's instructions. RT-PCR conditions were as described previously [79].

Supporting Information

Figure S1.

Scatter plots of normalized gene expression values obtained from three boutique array methods as compared to whole-array RMA across 36 ATH1 arrays. A, SBQ vs RMA. B, RMAPS vs RMA. C, RIMS vs RMA. All three boutique array normalizations used only a subset of 299 probe sets that correspond to genes represented on the AtMtDEFL array (37 DEFLs, 171 invariants, 91 marker genes). Each was compared to the reference RMA normalization, which included all 22,810 probe sets on the Affymetrix ATH1 array in the normalization process. Expression values were log2 transformed. All 37 probe sets on the ATH1 array that matched an Arabidopsis DEFL with at least 6 of 11 exact-match probes per probe set were included in the analysis. GEO accessions for ATH1 arrays included three biological replicates of: GSE1491 (seedlings), GSE5630 (cotyledons, leaves, senescent leaves), GSE5631 (roots), GSE5632 (carpels, stage 9 flowers, stamens), GSE5633 (stems), GSE5634 (old and young siliques), and GSE7227 (seeds).

https://doi.org/10.1371/journal.pone.0058992.s001

(TIF)

Figure S2.

geNorm ranking of expression stability of candidate Arabidopsis reference genes for use in qRT-PCR analysis. A, Expression stability was calculated using the custom chip microarray data. B, Expression stability for selected genes using qRT-PCR data. Refer to Materials and Methods for experimental details.

https://doi.org/10.1371/journal.pone.0058992.s002

(TIF)

Figure S3.

Gene expression profiles of Arabidopsis (A) defensins, (B) genes co-regulated with receptor-like protein kinase (FRK1; At2g19190) involved in early defense signaling, and (C) genes co-regulated with JA marker genes PDF1.2a (At5g44420) and/or coronatine-insensitive 1 (COI1; At2g39940). Treatments were: (1) 7-d-old seedling, (2) 14-d-old seedling, (3) 21-d-old root, (4) inflorescences, (5) siliques, (6) Col-0 Alternaria mock-inoculation, (7) Col-0 Alternaria-inoculated leaf, (8) dde2-2 Alternaria-inoculated leaf, (9) Pseudomonas mock-inoculation at 3 hpi, (10) PtoDC3000 inoculated leaves at 3 hpi, (11) PtoDC3000hrcC- inoculated leaves at 3 hpi, (12) PtoDC3000 AvRpt2 inoculated leaves at 3 hpi, (13) Pseudomonas mock-inoculation at 9 hpi, (14) PtoDC3000 inoculated leaves at 9 hpi, (15) PtoDC3000hrcC- inoculated leaves at 9 hpi, and (16) PtoDC3000 AvRpt2 inoculated leaves at 9 hpi. The heat map shows median scaling of SBQ normalized signal intensity values as described in Materials and Methods. Colors represent high transcript abundance (magenta), low transcript abundance (green), and average transcript abundance (white) as depicted in Figure 4.

https://doi.org/10.1371/journal.pone.0058992.s003

(TIF)

Figure S4.

Enhanced susceptibility of dde2-2 to Alternaria brassicicola (strain ATCC 96866) 4 days after inoculation. The third, fourth, and fifth true leaves of 21-d-old plants were inoculated by placing 10 µL droplets of water containing 105 spores/mL on the adaxial surfaces of the leaves. In wild type plants, necrosis is confined to the area of the inoculum, while chlorotic and water-soaked lesions spread beyond the inoculation droplet in dde2-2.

https://doi.org/10.1371/journal.pone.0058992.s004

(TIF)

Figure S5.

Raw log2 signal intensity distribution plots for AtDEFL array experiments profiling roots, leaves, siliques, and inflorescences. The three different color lines represent independent biological replicates. The large peak in these plots at low intensity values typically represents absent probe sets in the noise-level. Systematic shifts in these plots will be reduced or eliminated by most normalization methods, but changes in shape of the curve may reflect real biological differences among the samples.

https://doi.org/10.1371/journal.pone.0058992.s005

(TIF)

Figure S6.

Raw log2 signal intensity distribution plots for Affymetrix ATH1 array experiments profiling roots, leaves young siliques, and flowers. The three different color lines represent independent biological replicates. The distributions in these plots are much broader and less variable than the custom array, since more than 22,000 genes are represented. Nevertheless, some variations in peak height and shape are evident among different plant organs. GEO accessions represented: GSM131558-60 (roots), GSM131498-500 (leaves), GSM131685-7 (siliques), GSM131576-8 (flowers).

https://doi.org/10.1371/journal.pone.0058992.s006

(TIF)

Figure S7.

Heatmaps of Arabidospsis DEFL absolute expression after applying four different normalization algorithms. A, RMA using all 22,810 probe sets on the Affymetrix Arabidopsis ATH1 array. B, SBQ. C, RMAPS. D, RIMS. Normalizations B to D used only a subset of 299 probe sets (37 DEFLs, 171 invariants, 91 marker genes). Systematic intensity shifts for some arrays using the RIMS method in D are highlighted with arrows. Expression values have been log2 transformed. Two-dimensional hierarchical agglomerative clustering was applied to the set of 37 DEFLs (rows) and 36 arrays (columns) from the RMA-normalized data in A. This ordering of rows and columns was preserved for panels B to D. All 37 probe sets on the ATH1 array that matched an Arabidopsis DEFL with at least six of 11 probe sets were included in the analysis. The 36 arrays included three biological replicates for a wide variety of morphological structures and conditions obtained from GEO: GSE1491 (seedlings), GSE5630 (cotyledons, leaves, senescent leaves), GSE5631 (roots), GSE5632 (carpels, stage 9 flowers, stamens), GSE5633 (stems), GSE5634 (old and young siliques), and GSE7227 (seeds).

https://doi.org/10.1371/journal.pone.0058992.s007

(TIF)

Figure S8.

Heatmaps of Arabidopsis marker gene absolute expression after applying four different normalization algorithms. A, RMA using all 22,810 probe sets on the Affymetrix Arabidopsis ATH1 array. B, SBQ. C, RMAPS. D, RIMS. Normalizations B to D used only a subset of 299 probe sets (37 DEFLs, 171 invariants, 91 marker genes). Expression values have been log2 transformed. Two-dimensional hierarchical agglomerative clustering was applied to the set of 91 marker genes (rows) and 36 arrays (columns) from the RMA-normalized data in A. This ordering of rows and columns was preserved for panels B to D. All 91 marker gene probe sets on the ATH1 array are exactly identical to their counterparts on the AtDEFL array. The 36 arrays are the same as those described in Figure S3.

https://doi.org/10.1371/journal.pone.0058992.s008

(TIF)

Figure S9.

Heatmaps of Arabidopsis invariant gene absolute expression after applying four different normalization algorithms. A, RMA using all 22,810 probe sets on the Affymetrix Arabidopsis ATH1 array. B, SBQ. C, RMAPS. D, RIMS. Normalizations B to D used only a subset of 299 probe sets (37 DEFLs, 171 invariants, 91 marker genes). Expression values have been log2 transformed. Two-dimensional hierarchical agglomerative clustering was applied to the set of 37 DEFLs (rows) and 36 arrays (columns) from the RMA-normalized data in A. This ordering of rows and columns was preserved for panels B to D. All 171 invariant gene probe sets on the ATH1 array are exactly identical to their counterparts on the AtDEFL array. The 36 arrays are the same as those described in Figure S3.

https://doi.org/10.1371/journal.pone.0058992.s009

(TIF)

Figure S10.

Raw log2 signal intensity distribution plots for MtDEFL array experiments profiling leaves, roots, mycorrhizal roots, and root nodules. The three different color lines represent independent biological replicates. The large peak in these plots at low intensity values typically represents absent probe sets in the noise-level. Systematic shifts in these plots will be reduced or eliminated by most normalization methods, but changes in shape of the curve may reflect real biological differences among the samples.

https://doi.org/10.1371/journal.pone.0058992.s010

(TIF)

Figure S11.

Scatter plots showing correlation of normalized expression values obtained from three boutique array methods as compared to whole-array RMA across 62 MtDEFL arrays. A, SBQ vs. RMA. B, RMAPS vs. RMA. C, RIMS vs. RMA. All three boutique array normalizations used only a subset of 565 probe sets that correspond to genes represented on the MtDEFL array (370 DEFLs - black circles, 172 invariants - green plus signs, 23 marker genes - blue crosses). Each was compared to the reference RMA normalization, which included all 61,278 probe sets on the Affymetrix Medicago array in the normalization process. Expression values have been log2 transformed. All 370 probe sets on the Medicago array that matched a Medicago DEFL with at least six of 11 probe sets were included in the analysis. The 62 arrays included three biological replicates for a wide variety of tissues and conditions obtained from ArrayExpress and GEO: E-MEXP-1097 (flowers, leaves, nodules at various developmental stages, petioles, pods, roots, seeds at various developmental stages, stems and vegetative buds), E-MEXP-1092 (methyl-jasmonate and yeast-elicited cell suspensions and controls at multiple time points), GSE8131 (NAA and BAP-treated leaf explants), and GSE8115 (roots).

https://doi.org/10.1371/journal.pone.0058992.s011

(TIF)

Table S1.

qRT-PCR verification of microarray data using selected Arabidopsis genes.

https://doi.org/10.1371/journal.pone.0058992.s012

(XLSX)

Table S2.

Arabidopsis DEFL s custom chip SBQ normalized data.

https://doi.org/10.1371/journal.pone.0058992.s013

(XLSX)

Table S3.

Medicago DEFL s custom chip SBQ normalized data.

https://doi.org/10.1371/journal.pone.0058992.s014

(XLSX)

Table S4.

Arabidopsis genes differentially expressed (p<0.05) in response to A . brassicicola

https://doi.org/10.1371/journal.pone.0058992.s015

(XLSX)

Table S5.

Arabidopsis genes differentially (p<0.05) expressed following inoculations with several P. syringae pv. tomato strains.

https://doi.org/10.1371/journal.pone.0058992.s016

(XLSX)

Table S6.

List of significantly (p<0.05) expressed Medicago genes following mycorrhizal colonization.

https://doi.org/10.1371/journal.pone.0058992.s017

(XLSX)

Table S7.

List of significantly (p<0.05) expressed Medicago genes following S. meliloti inoculation.

https://doi.org/10.1371/journal.pone.0058992.s018

(XLSX)

Table S8.

List of significantly (p<0.05) expressed Medicago genes at 24 hpi with C. trifolii.

https://doi.org/10.1371/journal.pone.0058992.s019

(XLSX)

Table S9.

List of differentially expressed (p<0.05) Medicago genes in P. medicaginis -inoculated roots.

https://doi.org/10.1371/journal.pone.0058992.s020

(XLSX)

Table S10.

MtDEFL probe set mapping to Medicago Mt3.5v5 gene annotation.

https://doi.org/10.1371/journal.pone.0058992.s021

(XLSX)

Table S11.

MtDEFL individual probe mapping to Medicago Mt3.5v5 gene annotation.

https://doi.org/10.1371/journal.pone.0058992.s022

(XLSX)

Table S12.

Primer sequences of Arabidopsis genes used in this study.

https://doi.org/10.1371/journal.pone.0058992.s023

(XLSX)

Text S1.

Development of the custom AtMtDEFL array and robust data normalization methods. Mapping Medicago probe sets to the latest annotation of the Medicago gene annotation.

https://doi.org/10.1371/journal.pone.0058992.s024

(DOCX)

Acknowledgments

We thank Dr. Wayne Xu and the Minnesota Super Computing Institute, University of Minnesota, for bioinformatics support. Mention of a trademark, propriety product, or vendor does not constitute a guarantee or warranty of the product by the University of Minnesota or the USDA, and does not imply its approval to the exclusion of other products and vendors that might also be suitable.

Author Contributions

Conceived and designed the experiments: KATS KAV MT SN LW CJB JG FK DAS SKG MJH. Performed the experiments: MT KATS SN LW CJB JG FK DAS SKG MJH JFG-M LMC. Analyzed the data: MT KATS SN LW CJB JG FK DAS SKG MJH JFG-M KAV LMC. Contributed reagents/materials/analysis tools: MT KATS SN LW CJB JG FK DAS SKG MJH JFG-M. Wrote the paper: MT KATS SN LW CJB JG FK DAS SKG MJH JFG-M KAV LMC.

References

  1. 1. Boman HG (1995) Peptide antibiotics and their role in innate immunity. Annu Rev Immunol 13: 61–92.
  2. 2. Mygind PH, Fischer RL, Schnorr KM, Hansen MT, Sonksen CP, et al. (2005) Plectasin is a peptide antibiotic with therapeutic potential from a saprophytic fungus. Nature 437: 975–980.
  3. 3. Terras FRG, Eggermont K, Kovaleva V, Raikhel NV, Osborn RW, et al. (1995) Small cysteine-rich antifungal proteins from radish: Their role in host defense. Plant Cell 7: 573–588.
  4. 4. Thomma BPHJ, Broekaer WF (1998) Tissue-specific expression of plant defensin genes PDF2.1 and PDF2.2 in Arabidopsis thaliana. Plant Physiol Biochem 36: 533–537.
  5. 5. Thomma BP, Cammue BP, Thevissen K (2002) Plant defensins. Planta 216: 193–202.
  6. 6. Stotz HU, Thomson JG, Wang Y (2009) Plant defensins: defense, development and application. Plant Signal Behav 4: 1010–1012.
  7. 7. Graham MA, Silverstein KAT, Cannon SB, VandenBosch KA (2004) Computational identification and characterization of novel genes from legumes. Plant Physiol 135: 1179–1197.
  8. 8. Silverstein KAT, Moskal WA, Wu HC, Underwood BA, Graham MA, et al. (2007) Small cysteine-rich peptides resembling antimicrobial peptides have been under-predicted in plants. Plant J 51: 262–280.
  9. 9. Silverstein KAT, Graham MA, Paape TD, VandenBosch KA (2005) Genome organization of more than 300 defensin-like genes in Arabidopsis. Plant Physiol 138: 600–610.
  10. 10. Fedorova M, van de Mortel J, Matsumoto PA, Cho J, Town CD, et al. (2002) Genome-wide identification of nodule-specific transcripts in the model legume Medicago truncatula. Plant Physiol 130: 519–537.
  11. 11. Mergaert P, Nikovics K, Kelemen Z, Maunoury N, Vaubert D, et al. (2003) A novel family in Medicago truncatula consisting of more than 300 nodule-specific genes coding for small, secreted polypeptides with conserved cysteine motifs. Plant Physiol 132: 161–173.
  12. 12. Young N, Debellé F, Oldroyd G, Geurts R, Cannon S, et al. (2011) The Medicago genome provides insight into the evolution of rhizobial symbioses. Nature 480: 520–524.
  13. 13. Alunni B, Kevei Z, Redondo-Nieto M, Kondorosi A, Mergaert P, et al. (2007) Genomic organization and evolutionary insights on GRP and NCR genes, two large nodule-specific gene families in Medicago truncatula. Mol Plant-Microbe Interact 20: 1138–1148.
  14. 14. Gao AG, Hakimi SM, Mittanck CA, Wu Y, Woerner BM, et al. (2000) Fungal pathogen protection in potato by expression of a plant defensin peptide. Nat Biotechnol 18: 1307–1310.
  15. 15. Manners JM, Penninckx IA, Vermaere K, Kazan K, Brown RL, et al. (1998) The promoter of the plant defensin gene PDF1.2 from Arabidopsis is systemically activated by fungal pathogens and responds to methyl jasmonate but not to salicylic acid. Plant Mol Biol 38: 1071–1080.
  16. 16. Fujita M, Fujita Y, Noutoshi Y, Takahashi F, Narusaka Y, et al. (2006) Crosstalk between abiotic and biotic stress responses: a current view from the points of convergence in the stress signaling networks. Curr Opin Plant Biol 9: 436–442.
  17. 17. van de Velde W, Zehirov G, Szatmari A, Debreczeny M, Ishihara H, et al. (2010) Plant peptides govern terminal differentiation of bacteria in symbiosis. Science 327: 1122–1126.
  18. 18. Marshall E, Costa LM, Gutierrez-Marcos J (2011) Cysteine-Rich Peptides (CRPs) mediate diverse aspects of cell-cell communication in plant reproduction and development. J Exp Bot 62: 1677–1686.
  19. 19. Schopfer CR, Nasrallah ME, Nasrallah JB (1999) The male determinant of self-incompatibility in Brassica. Science 286: 1697–1700.
  20. 20. Takayama S, Shimosato H, Shiba H, Funato M, Che FS, et al. (2001) Direct ligand-receptor complex interaction controls Brassica self-incompatibility. Nature 413: 534–538.
  21. 21. Okuda S, Tsutsui H, Shiina K, Sprunck S, Takeuchi H, et al. (2009) Defensin-like polypeptide LUREs are pollen tube attractants secreted from synergid cells. Nature 458: 357–361.
  22. 22. Amien S, Kliwer I, Márton ML, Debener T, Geiger D, et al. (2010) Defensin-like ZmES4 mediates pollen tube burst in maize via opening of the potassium channel KZM1. PLoS Biol 8(6): e1000388 .
  23. 23. Allen A, Snyder AK, Preuss M, Nielsen EE, Shah DM, et al. (2008) Plant defensins and virally encoded fungal toxin KP4 inhibit plant root growth. Planta 227: 331–339.
  24. 24. Kondo T, Kajita R, Miyazaki A, Hokoyama M, Nakamura-Miura T, et al. (2009) Stomatal density is controlled by a mesophyll-derived signaling molecule. Plant Cell Physiol 51: 1–8.
  25. 25. Sugano SS, Shimada T, Imai Y, Okawa K, Tamai A, et al. (2009) Stomagen positively regulates stomatal density in Arabidopsis. Nature 463: 241–244.
  26. 26. Costa LM, Yuan J, Rouster J, Paul W, Dickinson H, et al. (2012) Maternal control of nutrient allocation in plant seeds by genomic imprinting. Curr Biol 22: 160–165.
  27. 27. Stotz HU, Spence B, Wang Y (2009) A defensin from tomato with dual function in defense and development. Plant Mol Biol 71: 131–143.
  28. 28. Schmid M, Davison TS, Henz SR, Pape UJ, Demar M, et al. (2005) A gene expression map of Arabidopsis thaliana development. Nat Genet 37: 501–506.
  29. 29. Benedito VA, Torres-Jerez I, Murray JD, Andriankaja A, Allen S, et al. (2008) A gene expression atlas of the model legume Medicago truncatula. Plant J 55: 504–513.
  30. 30. Gutierrez-Marcos JF, Costa LM, Biderre-Petit C, Khbaya B, O’Sullivan DM, et al. (2004) Maternally expressed gene1 is a novel endosperm transfer cell-specific gene with a maternal parent-of-origin pattern of expression. Plant Cell 16: 1288–1301.
  31. 31. Liu WM, Mei R, Di X, Ryder TB, Hubbell E, et al. (2002) Analysis of high density expression microarrays with signed-rank call algorithm. Bioinformatics 18: 1593–1599.
  32. 32. Smyth GK, Speed T (2003) Normalization of cDNA microarray data. Methods 31: 265–273.
  33. 33. Irizarry RA, Hobbs B, Collin F, Beazer-Barclay YD, Antonellis KJ, et al. (2003) Exploration, normalization, and summaries of high density oligonucleotide array probe level data. Biostatistics 4: 249–264.
  34. 34. Bolstad BM, Irizarr RA, Åstrand M, Speed TP (2003) A comparison of normalization methods for high density oligonucleotide array data based on variance and bias. Bioinformatics 19: 185–193.
  35. 35. Wilson DL, Buckley MJ, Helliwell CA, Wilson IW (2003) New normalization methods for cDNA microarray data. Bioinformatics 19: 1325–1332.
  36. 36. Sato M, Mitra RM, Coller J, Wang D, Spivey NW, et al. (2007) A high-performance, small-scale microarray for expression profiling of many samples in Arabidopsis-pathogen studies. Plant J 49: 565–577.
  37. 37. Vandesompele J, De Preter K, Pattyn F, Poppe B, Van Roy N, et al. (2002) Accurate normalization of real-time quantitative RT-PCR data by geometric averaging of multiple internal control genes. Genome Biol 3: research0034–research0034.11.
  38. 38. Roeder AHK, Yanofsky MF (2006) Fruit Development in Arabidopsis. The Arabidopsis Book 4: e0075 .
  39. 39. Alvarez-Buylla ER, Benítez M, Corvera-Poiré A, Cador AC, de Folter S, et al. (2010) Flower Development. The Arabidopsis Book 8: e0127 .
  40. 40. Higashiyama T (2011) Peptide signaling in pollen-pistil interactions. Plant Cell Physiol 51: 177–189.
  41. 41. Vanoosthuyse V, Miege C, Dumas C, Cock JM (2001) Two large Arabidopsis thaliana gene families are homologous to the Brassica gene superfamily that encodes pollen coat proteins and the male component of the self-incompatibility response. Plant Mol Biol 16: 17–34.
  42. 42. Moore I, Galweiler L, Grosskopf D, Schell J, Palme K (1998) Transcription activation system for regulated gene expression in transgenic plants. Proc Natl Acad Sci USA 95: 376–381.
  43. 43. van Wees SCM, Chang H-S, Zhu T, Glazebrook J (2003) Characterization of the early response of Arabidopsis to Alternaria brassicicola infection using expression profiling. Plant Physiol 132: 606–617.
  44. 44. von Malek B, van der Graaff E, Schneitz K, Keller B (2002) The Arabidopsis male-sterile mutant dde2-2 is defective in the allene oxide synthase gene encoding one of the key enzymes of the jasmonic acid biosynthesis pathway. Planta 216: 187–192.
  45. 45. AbuQamar S, Chen X, Dhawan R, Bluhm B, Salmeron J, et al. (2006) Expression profiling and mutant analysis reveals complex regulatory networks involved in Arabidopsis response to Botrytis infection. Plant J 48: 28–44.
  46. 46. Glazebrook J (2005) Contrasting mechanisms of defense against biotrophic and necrotrophic pathogens. Ann Rev Phytopathol 43: 205–227.
  47. 47. Penninckx IA, Thomma BP, Buchala A, Metraux JP, Broekaert WF (1998) Concomitant activation of jasmonate and ethylene response pathways is required for induction of a plant defensin gene in Arabidopsis. Plant Cell 10: 2103–2113.
  48. 48. Lorenzo O, Solano R (2005) Molecular players regulating the jasmonate signaling network. Curr Opin Plant Biol 8: 532–540.
  49. 49. Asai T, Tena G, Plotnikova J, Willmann MR, Chiu WL, et al. (2002) MAP kinase signaling cascade in Arabidopsis innate immunity. Nature 415: 977–983.
  50. 50. Ameline-Torregrosa CA, Cazaux M, Danesh D, Chardon F, Cannon SB, et al. (2008) Genetic dissection of resistance to anthracnose and powdery mildew in Medicago truncatula.. Mol Plant-Microbe Interact 21: 61–69.
  51. 51. Samac DA, Peñuela S, Schnurr JA, Hunt EN, Foster-Hartnett D, et al. (2011) Expression of coordinately regulated defence response genes and analysis of their role in disease resistance in Medicago truncatula. Mol Plant Pathol 12: 786–798.
  52. 52. Meyers BC, Lee DK, Vu TH, Tej SS, Edberg SB, et al. (2004) Arabidopsis MPSS. An online resource for quantitative expression analysis. Bioinformatics 135: 801–813.
  53. 53. Jones-Rhoades MW, Borevitz JO, Preuss D (2007) Genome-wide expression profiling of the Arabidopsis female gametophyte identifies families of small, secreted proteins. PLoS Genet 3: 1848–1861.
  54. 54. Dresselhaus T, Marton ML (2009) Micropylar pollen tube guidance and burst: adapted from defense mechanisms. Curr Opin Plant Biol 12: 773–780.
  55. 55. Hanks JN, Snyder AK, Graham MA, Shah RK, Blaylock LA, et al. (2005) Defensin gene family in Medicago truncatula: structure, expression and induction by signal molecules. Plant Mol Biol 58: 385–399.
  56. 56. Kaur J, Thokala M, Robert-Seilaniantz A, Zhao P, Peyret H, et al. (2012) Subcellular targeting of an evolutionarily conserved plant defensin MtDef4.2 determines the outcome of plant-pathogen interaction in transgenic Arabidopsis. Mol Plant Pathol 13: 1032–1046.
  57. 57. Watanabe M, Ito A, Takada Y, Ninomiya C, Kakizaki T, et al. (2000) Highly divergent sequences of the pollen self-incompatibility (S) gene in class-I S haplotypes of Brassica campestris (syn. rapa) L. FEBS Lett 473: 139–144.
  58. 58. Shiba H, Iwano M, Entani T, Ishimot K, Shimosato H, et al. (2002) The dominance of alleles controlling self-incompatibility in Brassica pollen is regulated at the RNA level. Plant Cell 14: 491–504.
  59. 59. Zhou CX, Zhang YL, Xiao L, Zheng M, Leung KM, et al. (2004) An epididymis-specific β-defensin is important for the initiation of sperm maturation. Nat Cell Bio 6: 458–464.
  60. 60. Spelbrink RG, Dilmac N, Allen A, Smith TJ, Shah DM, et al. (2004) Differential antifungal and calcium channel-blocking activity among structurally related plant defensins. Plant Physiol 135: 2055–2067.
  61. 61. Zhu YL, Song QJ, Hyten DL, Van Tassell CP, Matukumalli LK, et al. (2003) Single-nucleotide polymorphisms in soybean. Genetics 163: 1123–1134.
  62. 62. Lamblin AFJ, Crow JA, Johnson JE, Silverstein KAT, Kunau TM, et al. (2003) MtDB: a database for personalized data mining of the model legume Medicago truncatula transcriptome. Nucleic Acids Res 31: 196–201.
  63. 63. He J, Benedito VA, Wang M, Murray JD, Zhao PX, et al. (2009) The Medicago truncatula gene expression atlas web server. Bioinformatics 10: 441.
  64. 64. Nafisi M, Goregaoker S, Botanga CJ, Glawischnig E, Olsen CE, et al. (2007) Arabidopsis cytochrome P450 monooxygenase 71A13 catalyzes the conversion of indole-3-acetaldoxime in camalexin synthesis. Plant Cell 19: 2039–2052.
  65. 65. Glazebrook J, Ausubel FM (1994) isolation of phytoalexin-deficient mutants of Arabidopsis thaliana and characterization of their interactions with bacterial pathogens. Proc Natl Acad Sci USA 91: 8955–8959.
  66. 66. Wang L, Tsuda K, Sato M, Cohen JD, Katagiri F, et al. (2009) Arabidopsis CaM binding protein CBP60g contributes to MAMP-induced SA accumulation and is involved in disease resistance against Pseudomonas syringae. PLoS Pathogens 5(2): e100030.
  67. 67. Wang L, Mitra RM, Hasselmann KD, Sato M, Lenarz-Wyatt L, et al. (2008) The genetic network controlling the Arabidopsis transcriptional response to Pseudomonas syringae pv. maculicola: roles of major regulators and the phytotoxin coronatine. Mol Plant-Microbe Interact 21: 1408–1420.
  68. 68. Lohar DP, Sharopova N, Endre G, Peñuela S, Samac D, et al. (2006) Transcript analysis of early nodulation events in Medicago truncatula. Plant Physiol 140: 221–234.
  69. 69. Wang HL, Grusak MA (2005) Structure and development of Medicago truncatula pod wall and seed coat. Ann Bot 95: 737–747.
  70. 70. Tesfaye M, Yang SS, Lamb JF, Jung HJ, Samac DA, et al. (2009) Medicago truncatula as a model for dicot cell wall development. BioEnergy Res 2: 59–76.
  71. 71. Ehrhardt DW, Atkinson EM, Long SR (1992) Depolarization of alfalfa root hair membrane potential by Rhizobium meliloti Nod factors. Science 256: 998–1000.
  72. 72. St-Arnaud M, Hamel C, Vimard B, Caron M, Fortin JA (1996) Enhanced hyphal growth and spore production of the arbuscular mycorrhizal fungus Glomus intraradices in an in vitro system in the absence of host roots. Mycol Res 100: 328–332.
  73. 73. Liu J, Blaylock L, Endre G, Cho J, Town CD, et al. (2003) Transcript profiling coupled with spatial expression analyses reveals genes involved in distinct developmental stages of the arbuscular mycorrhizal symbiosis. Plant Cell 15: 2106–2123.
  74. 74. van Engelen FA, Molthoff JW, Conner AJ, Nap JP, Pereira A, et al. (1995) pBINPLUS: An improved plant transformation vector based on pBIN19. Transgenic Res 4: 288–290.
  75. 75. Rutherford S, Brandizzi F, Townley H, Craft J, Wang Y, et al. (2005) Improved transcriptional activators and their use in mis-expression traps in Arabidopsis. Plant J 43: 769–788.
  76. 76. Shirzadegan M, Christie P, Seemann JR (1991) An efficient method for isolation of RNA from tissue cultured plant cells. Nucleic Acids Res 19: 6055.
  77. 77. Gentleman RC, Carey VJ, Bates DM, Bolstad B, Dettling M, et al. (2004) Bioconductor: open software development for computational biology and bioinformatics. Genome Biol 5: R80.
  78. 78. Benjamini Y, Hochberg Y (1995) Controlling the false discovery rate: a practical and powerful approach to multiple testing. J R Stat Soc Series B Stat Methodol 57: 289–300.
  79. 79. Tesfaye M, Samac DA, Vance CP (2006) Insights into symbiotic nitrogen fixation in Medicago truncatula. Mol Plant-Microbe Interact 19: 330–341.