MADS about MOSS

Classic MIKC-type MADS-box genes (MIKC^c) play diverse and crucial roles in angiosperm development, the most studied and best understood of which is the specification of floral organ identities. To shed light on how the flower evolved, phylogenetic and functional analyses of genes involved in its ontogeny, such as the MIKC^c genes, must be undertaken in as broad a selection as possible of plants with disparate ancestries. Since little is known about the functions of these genes in non-seed plants, we investigated the developmental roles of a subset of the MIKC^c genes present in the moss, Physcomitrella patens, which is positioned informatively near the base of the land plant evolutionary tree. We observed that transgenic lines possessing an antisense copy of a MIKC^c gene characteristically displayed knocked-down expression of the corresponding native MIKC^c gene as well as multiple diverse phenotypic alterations to the haploid gametophytic and diploid sporophytic generations of the life cycle.¹ In this addendum, we re-examine our findings in the light of recent pertinent literature and provide additional data concerning the effects of simultaneously knocking out multiple MIKC^c genes in this moss.Key words: Physcomitrella, moss, MADS-box gene functions, gene knock-down, gene knockout, gene expression, evo-devoThe moss, Physcomitrella patens, is the only non-seed plant that is amenable to an investigation of MADS-box gene function comparable to that achieved in angiosperms. P. patens possesses six MIKC^c genes which cluster into two distinct phylogenetic clades.² We recently reported a functional genetic analysis of the three genes (PPM1, PPM2 and PpMADS1) within the PPM2-like clade as an initial contribution towards gaining an understanding of the role(s) of MIKC^c genes in this moss.¹By fusing the respective MIKC^c promoters to a GUS reporter gene, we found that both PPM1 and PpMADS1 exhibited fairly ubiquitous expression patterns in both gametophytic and sporophytic tissues. The levels of PPM1 expression were generally higher than those of PpMADS1, and PpMADS1 was not expressed in antheridia, suggesting subtle differences in the functions of these genes. The observed patterns of widespread expression resemble those characterising the majority of vascular, non-seed plant MIKC^c genes^3–7 and accord with RT-PCR results of Quodt and coworkers.² Our in situ GUS expression and RT-PCR results¹ showed that PPM2 was not expressed or was expressed at levels too low to be detected by these methods. Conversely, the original isolation of PPM2 cDNA⁸ and data from more recent expression studies² indicated that PPM2 is expressed (albeit inconsistently and weakly) ubiquitously with elevated levels of expression sometimes observed in gametangia, sporophytic feet and basal portions of sporophytic setae.² The contradictory expression data for PPM2 may derive from differences between the PPM2-reporter gene constructs used by the respective research groups^1,2 or perhaps from variations in moss culture conditions.We also employed an antisense approach designed to knock down expression of PPM1, and perhaps closely related MIKC^c genes, in order to discern MADS-box gene function in P. patens. Knocked-down strains displayed a complex mutant phenotype comprising delayed gametangia formation and sporophyte production, diminished sporophyte yields, and morphological abnormalities in both leaves and sporophytes, findings that are generally consistent with the ubiquitous expression pattern of PPM1¹ and PPM2''s expression as described by Quodt et al.²The phenotypes of strains with single gene knockouts of PPM1, PPM2 or PpMADS1 appeared to be perfectly normal, not displaying any of the phenotypic alterations observed in PPM1 gene knock-down mutants. While it is possible that subtle, transient or conditional phenotypic changes went unnoticed, it seems more probable that genetic redundancy is responsible for these results since the PPM2-like genes exhibit a very high level of sequence similarity. In an effort to circumvent the problem of functional redundancy, we generated all double knockout combinations for PPM1, PPM2 and PpMADS1. However, the double mutants were also phenotypically unchanged. Finally we attempted to produce triple mutants by co-transforming single PPM2 knockout lines with PPM1 and PpMADS1 linear knockout constructs. Of the 31 stable transformants from two transformation experiments, 55% were shown to be double mutants in which the original PPM2 knockout was accompanied by a second gene knockout in either PPM1 or PpMADS1. However, no triple knockouts were obtained. Given the knockout frequencies generally observed in batch transformation experiments in our laboratory and those of others,⁹ between two and five of the transformants had been expected to be triple mutants. These preliminary data, albeit involving a relatively small sample of transformants, suggest that PPM1, PPM2 and PpMADS1 triple knockouts may be lethal.We have related compelling evidence that functionally redundant PPM2-like MIKC^c genes are involved in several aspects of the moss developmental program. It has been argued that broad expression patterns like theirs represent the ancestral state of MADS-box genes in land plants, and that the sporophytic- and organ-specific expression patterns that characterise many MIKC^c genes in extant spermatophytes, including those that specify floral organ identity, correspond to a derived condition that evolved in the spermatophyte lineage following its separation from lineages that led to bryophytes and ferns and fern allies.¹⁰ Nevertheless, it is the apparent participation of PPM2-like genes in the formation of gametangia (the differentiation of reproductive organs from non-reproductive tissues at the gametophore apex) that is particularly interesting and assumes a special significance because of its analogy to the proposed role for ancestors of seed plant C-function MADS-box genes (identifying those regions of the vegetative SAM that will become reproductive organs).11 Furthermore, expression studies of MIKC^c genes in two charophycean algae, the presumed progenitors of all terrestrial plants,^12–14 suggest that they too are involved in haploid reproductive cell differentiation.¹⁵ While these functional similarities do not infer orthology and may be coincidental, we should not discount yet the admittedly controversial hypothesis that some MIKC^c genes in non-seed plants, for example PPM2-like genes of Physcomitrella, are homologous to spermatophyte class C genes and that the ancient role proposed for ancestral class C genes¹¹ has been conserved, in some form, in all major terrestrial plant taxa.     

Characterization of the <Emphasis Type="Italic">Selaginella remotifolia</Emphasis> MADS-box gene

Recent progress in plant molecular genetics has revealed that floral organ development is regulated by several homeotic selector genes, most of which belong to the MADS-box gene family. Here we report on SrMADS1, a MIKC^c-type MADS-box gene from Selaginella, a spikemoss belonging to the lycophytes. SrMADS1 phylogenetically forms a monophyletic clade with genes of the LAMB2 group, which are MIKC^c genes of the clubmoss Lycopodium, and is expressed in whole sporophytic tissues except roots and rhizophores. Our results and the previous report on Lycopodium MIKC^c genes suggest that the ancestral MIKC^c gene of primitive dichotomous plants in the early Devonian was involved in the development of basic sporophytic tissues such as shoot, stem, and sporangium. Electronic Publication     

The Complete Mitochondrial Genome Sequence of the Hornwort <Emphasis Type="Italic">Megaceros</Emphasis><Emphasis Type="Italic">aenigmaticus</Emphasis> Shows a Mixed Mode of Conservative Yet Dynamic Evolution in Early Land Plant Mitochondrial Genomes

Land plants possess some of the most unusual mitochondrial genomes among eukaryotes. However, in early land plants these genomes resemble those of green and red algae or early eukaryotes. The question of when during land plant evolution the dramatic change in mtDNAs occurred remains unanswered. Here we report the first completely sequenced mitochondrial genome of the hornwort, Megaceros aenigmaticus, a member of the sister group of vascular plants. It is a circular molecule of 184,908 base pairs, with 32 protein genes, 3 rRNA genes, 17 tRNA genes, and 30 group II introns. The genome contains many genes arranged in the same order as in those of a liverwort, a moss, several green and red algae, and Reclinomonas americana, an early-branching eukaryote with the most ancestral form of mtDNA. In particular, the gene order between mtDNAs of the hornwort and Physcomitrella patens (moss) differs by only 8 inversions and translocations. However, the hornwort mtDNA possesses 4 derived features relative to green alga mtDNAs—increased genome size, RNA editing, intron gains, and gene losses—which were all likely acquired during the origin and early evolution of land plants. Overall, this genome and those of other 2 bryophytes show that mitochondrial genomes in early land plants, unlike their seed plant counterparts, exhibit a mixed mode of conservative yet dynamic evolution. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Libo Li and Bin Wang contributed equally to this work.     

Revelation of ancestral roles of KNOX genes by a functional analysis of <Emphasis Type="Italic">Physcomitrella</Emphasis> homologues

KNOX genes are indispensable elements of indeterminate apical growth programmes of vascular plant sporophytes. Since little is known about the roles of such genes in non-vascular plants, functional analysis of moss KNOX homologues (MKN genes) was undertaken using the genetically amenable model plant, Physcomitrella patens. Three MKN genes were inactivated by targeted gene knockout to produce single, double and triple mutants. MKN2 (a class 1 KNOX gene) mutants were characterised by premature sporogenesis, abnormal sporophyte ontogeny and irregular spore development. MKN4 (a second class 1 gene) mutants were phenotypically normal. MKN1-3 (a class 2 KNOX gene) mutants exhibited defects in spore coat morphology. Analysis of double and triple mutants revealed that the abnormal sporophytic phenotype of MKN2 mutants was accentuated by mutating MKN4 and to a lesser degree by mutating MKN1-3. The aberrant spore phenotype of MKN1-3 and MKN2 mutants was exacerbated by mutating MKN4. This study provides the first instance in which an abnormal phenotype has been associated with the disruption of a class 2 KNOX gene as well as the first demonstrated case of functional redundancy between a class 1 and a class 2 KNOX gene. We conclude that KNOX genes play significant roles in programming sporophytic development in moss and we provide evidence that ancestral function(s) of this gene family were instrumental in the successful transition of plants to a terrestrial environment.     

Cloning of the PpMSH-2 cDNA of Physcomitrella patens, a moss in which gene targeting by homologous recombination occurs at high frequency

In the moss Physcomitrella patens integrative transformants from homologous recombination are obtained at an efficiency comparable to that found for yeast. This property, unique in the plant kingdom, allows the knockout of specific genes. It also makes the moss a convenient model to study the regulation of homologous recombination in plants. We used degenerate oligonucleotides designed from AtMSH2 from Arabidopsis thaliana and other known MutS homologues to isolate the P. patens MSH2 (PpMSH2) cDNA. The deduced sequence of the PpMSH2 protein is respectively 60.8% and 59.6% identical to the maize and A. thaliana MSH2. Phylogenic studies show that PpMSH2 is closely related to the group of plant MSH2 proteins. Southern analysis reveals that the gene exists as a single copy in the P. patens genome.     

The moss genes <Emphasis Type="Italic">PpSKI1</Emphasis> and <Emphasis Type="Italic">PpSKI2</Emphasis> encode nuclear SnRK1 interacting proteins with homologues in vascular plants

The yeast Snf1, animal AMPK, and plant SnRK1 protein kinases constitute a family of related proteins that have been proposed to serve as metabolic sensors of the eukaryotic cell. We have previously reported the characterization of two redundant SnRK1 encoding genes (PpSNF1a and PpSNF1b) in the moss Physcomitrella patens. Phenotypic analysis of the snf1a snf1b double knockout mutant suggested that SnRK1 is important for the plant’s ability to recognize and adapt to conditions of limited energy supply, and also suggested a possible role of SnRK1 in the control of plant development. We have now used a yeast two-hybrid system to screen for PpSnf1a interacting proteins. Two new moss genes were found, PpSKI1 and PpSKI2, which encode highly similar proteins with homologues in vascular plants. Fusions of the two encoded proteins to the green fluorescent protein localize to the nucleus. Knockout mutants for either gene have an excess of gametophores under low light conditions, and exhibit reduced gametophore stem lengths. Possible functions of the new proteins and their connection to the SnRK1 kinase are discussed.     

The use of the phosphomannose isomerase gene as alternative selectable marker for Agrobacterium-mediated transformation of flax (Linum usitatissimum)

In order to meet the future requirement of using non-antibiotic resistance genes for the production of transgenic plants, we have adapted the selectable marker system PMI/mannose to be used in Agrobacterium-mediated transformation of flax (Linum usitatissimum L.) cv. Barbara. The Escherichia coli pmi gene encodes a phosphomannose isomerase (E.C. 5.1.3.8) that converts mannose-6-phosphate, an inhibitor of glycolysis, into fructose-6-phosphate (glycolysis intermediate). Its expression in transformed cells allows them to grow on mannose-selective medium. The Agrobacterium tumefaciens strain GV3101 (pGV2260) harbouring the binary vector pNOV2819 that carries the pmi gene under the control of the Cestrum yellow leaf curling virus constitutive promoter was used for transformation experiments. Transgenic flax plants able to root on mannose-containing medium were obtained from hypocotyl-derived calli that had been selected on a combination of 20 g L⁻¹ sucrose and 10 g L⁻¹ mannose. Their transgenic state was confirmed by PCR and Southern blotting. Transgene expression was detected by RT-PCR in leaves, stems and roots of in vitro grown primary transformants. The mean transformation efficiency of 3.6%, that reached 6.4% in one experiment was comparable to that obtained when using the nptII selectable marker on the same cultivar. The ability of T1 seeds to germinate on mannose-containing medium confirmed the Mendelian inheritance of the pmi gene in the progeny of primary transformants. These results indicate that the PMI/mannose selection system can be successfully used for the recovery of flax transgenic plants under safe conditions for human health and the environment.     

Alternation of generations – unravelling the underlying molecular mechanism of a 165‐year‐old botanical observation

Characteristically, land plants exhibit a life cycle with an ‘alternation of generations’ and thus alternate between a haploid gametophyte and a diploid sporophyte. At meiosis and fertilisation the transitions between these two ontogenies take place in distinct single stem cells. The evolutionary invention of an embryo, and thus an upright multicellular sporophyte, in the ancestor of land plants formed the basis for the evolution of increasingly complex plant morphologies shaping Earth's ecosystems. Recent research employing the moss Physcomitrella patens revealed the homeotic gene BELL1 as a master regulator of the gametophyte‐to‐sporophyte transition. Here, we discuss these findings in the context of classical botanical observations.     

Abiotic stress response in the moss <Emphasis Type="Italic">Physcomitrella patens</Emphasis>: evidence for an evolutionary alteration in signaling pathways in land plants

The mechanisms plants use to adapt to abiotic stress have been widely studied in a number of seed plants. Major research has been focused on the isolation of stress-responsive genes as a means to understand the molecular events underlying the adaptation process. To study stress-related gene regulation in the moss Physcomitrella patens we have isolated two cDNAs showing homology to highly conserved small hydrophobic proteins from different seed plants. The corresponding genes are up-regulated by dehydration, salt, sorbitol, cold and the hormone abscisic acid, indicating overlapping pathways are involved in the control of these genes. Based on the molecular characterization of the moss homologs we propose that signaling pathways in response to abiotic stress may have been altered during the evolution of land plants.Abbreviation ABA Abscisic acid - EST Expressed sequence tag     

Defense-related gene expression and enzyme activities in transgenic cotton plants expressing an endochitinase gene from <Emphasis Type="Italic">Trichoderma virens</Emphasis> in response to interaction with <Emphasis Type="Italic">Rhizoctonia solani</Emphasis>

There are many reports on obtaining disease-resistance trait in plants by overexpressing genes from diverse organisms that encode chitinolytic enzymes. Current study represents an attempt to dissect the mechanism underlying the resistance to Rhizoctonia solani in cotton plants expressing an endochitinase gene from Trichoderma virens. Several assays were developed that provided a powerful demonstration of the disease protection obtained in the transgenic cotton plants. Transgene-dependent endochitinase activity was confirmed in various tissues and in the medium surrounding the roots of transformants. Biochemical and molecular analyses conducted on the transgenic plants showed rapid/greater induction of ROS, expression of several defense-related genes, and activation of some PR enzymes and the terpenoid pathway. Interestingly, even in the absence of a challenge from the pathogen, the basal activities of some of the defense-related genes and enzymes were higher in the endochitinase-expressing cotton plants. This elevated defensive state of the transformants may act synergistically with the potent, transgene-encoded endochitinase activity to confer a strong resistance to R. solani infection. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Reversible inactivation of a foreign gene, hph, during the asexual cycle in Neurospora crassa transformants

Summary A plasmid construct carrying the hygromycin phosphotransferase (hph) gene fused to the expression elements of the trpC gene of Aspergillus nidulans was used to obtain hygromycin B (Hyg)-resistant transformants of Neurospora crassa. The plasmid does not have any homology with the N. crassa genome. Here we demonstrate that most of the transformants arise from integration of the transforming DNA into only one of the nuclei present in the protoplasts. Furthermore, in most of the transformants the integrated transforming DNA is physically stable after growth of the transformants for about 25 nuclear divisions without Hyg selection, in spite of being present in multiple copies. In transformants carrying only a single insertion, phenotypic expression of the hph gene remains unaltered in conidial isolates obtained withoug Hyg selection. On the other hand, about 40% of transformants harbouring plasmid DNA integrated at more than one location yield conidial isolates showing reversible inactivation of the hph genes. Interestingly, the presence of methylated cytosine residues in the integrated DNA is strongly correlated with the number of plasmid copies. The hph genes are heavily methylated in transformants harbouring multiple copies but not in those harbouring only one copy of the plasmid. Phenotypic expression of the inactive hph genes can be restored by growing the transformants either under Hyg selection pressure or in the presence of 5-azacytidine. In the first case the hph genes are again inactivated when Hyg selection pressure is removed, while the activation of the hph gene by 5-azacytidine gives stable Hyg^r strains.Dedicated to Dr. T.A. Trautner on the occasion of his 60^th birthday     

The influence of matrix attachment regions on transgene expression in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> wild type and gene silencing mutants

Many studies in both animal and plant systems have shown that matrix attachment regions (MARs) can increase the expression of flanking transgenes. However, our previous studies revealed no effect of the chicken lysozyme MARs (chiMARs) on transgene expression in the first generation transgenic Arabidopsis thaliana plants transformed with a β-glucuronidase gene (uidA) unless gene silencing mutants were used as genetic background for transformation. In the present study, we investigated why chiMARs do not influence transgene expression in transgenic wild-type Arabidopsis plants. We first studied the effect of chiMARs on transgene expression in the progeny of primary transformants harboring chiMAR-flanked T-DNAs. Our data indicate that chiMARs do not affect transgene expression in consecutive generations of wild-type A. thaliana plants. Next, we examined whether these observed results in A. thaliana transformants are influenced by the applied transformation method. The results from in vitro transformed A. thaliana plants are in accordance with those from in planta transformed A. thaliana plants and again reveal no influence of chiMARs on transgene expression in A. thaliana wild-type transformants. The effect of chiMARs on transgene expression is also examined in in vitro transformed Nicotiana tabacum plants, but as for A. thaliana, the transgene expression in tobacco transformants is not altered by the presence of chiMARs. Taken together, our results show that the applied method or the plant species used for transformation does not influence whether and how chiMARs have an effect on transgene expression. Finally, we studied the effect of MARs (tabMARs) of plant origin (tobacco) on the transgene expression in A. thaliana wild-type plants and suppressed gene silencing (sgs2) mutants. Our results clearly show that similar to chiMARs, the tobacco-derived MARs do not enhance transgene expression in a wild-type background but can be used to enhance transgene expression in a mutant impaired in gene silencing. Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users. Miguel F.C. De Bolle, Katleen M.J. Butaye Contributed equally to this work     

Loss of GH3 function does not affect phytochrome-mediated development in a moss, Physcomitrella patens

Auxin-induced gene expression is described for a variety of different genes including the SAUR-, Aux/IAA- and GH3-families, members of which have been found in seed plants. The precise function of GH3-like proteins in plant development is not well characterised yet. Mutant analysis in Arabidopsis thaliana indicates a possible role for GH3-like proteins in connecting auxin and light signal transduction. Here, we report the isolation of three different GH3-like homologues from a lower land plant, the moss Physcomitrella patens. Two of the GH3-like homologues were chosen for further characterisation. Both genes are expressed in gametophytic tissues, with expression starting very early in moss development. Knockout plants were generated and analysed. In comparison to white-light growth, cultivation of the wild type and knockout plants under red-light conditions resulted in a delay in gametophytic tissue development. The leafy moss plants displayed an elongated phenotype. Growth delay and elongation were even stronger under far-red light conditions. No obvious differences between wild type and knockout plants could be detected under the examined conditions, indicating functional redundancy of the two genes.     

The cellulose synthase (<Emphasis Type="Italic">CESA</Emphasis>) gene superfamily of the moss <Emphasis Type="Italic">Physcomitrella patens</Emphasis>

The CESA gene superfamily of Arabidopsis and other seed plants comprises the CESA family, which encodes the catalytic subunits of cellulose synthase, and eight families of CESA-like (CSL) genes whose functions are largely unknown. The CSL genes have been proposed to encode processive β-glycosyl transferases that synthesize noncellulosic cell wall polysaccharides. BLAST searches of EST and shotgun genomic sequences from the moss Physcomitrella patens (Hedw.) B.S.G. were used to identify genes with high similarity to vascular plant CESAs, CSLAs, CSLCs, and CSLDs. However, searches using Arabidopsis CSLBs, CSLEs, and CSLGs or rice CSLFs or CSLHs as queries identified no additional CESA superfamily members in P. patens, indicating that this moss lacks representatives of these families. Intron insertion sites are highly conserved between Arabidopsis and P. patens in all four shared gene families. However, phylogenetic analysis strongly supports independent diversification of the shared families in mosses and vascular plants. The lack of orthologs of vascular plant CESAs in the P. patens genome indicates that the divergence of mosses and vascular plants predated divergence and specialization of CESAs for primary and secondary cell wall syntheses and for distinct roles within the rosette terminal complexes. In contrast to Arabidopsis, the CSLD family is highly represented among P. patens ESTs. This is consistent with the proposed function of CSLDs in tip growth and the central role of tip growth in the development of the moss protonema. Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users. Accession numbers: DQ417756, DQ417757, DQ898284–6, DQ898147–54, DQ902545–51.     

Real-time PCR assay for the simultaneous quantification of nitrifying and denitrifying bacteria in activated sludge

In order to improve wastewater treatment processes, a need exists for tools that rapidly give detailed insight into the community structure of activated sludge, supplementary to chemical and physical data. In this study, the advantages of microarrays and quantitative polymerase chin reaction (PCR) methods were combined into a real-time PCR assay that allows the simultaneous quantification of phylogenetic and functional genes involved in nitrification and denitrification processes. Simultaneous quantification was possible along a 5-log dynamic range and with high linear correlation (R ² > 0.98). The specificity of the assay was confirmed by cloning and sequencing analyses of PCR amplicons obtained from activated sludge. The real-time assay was validated on mixed liquid samples of different treatment plants, which varied in nitrogen removal rate. The abundance of ammonia oxidizers was in the order of magnitude of 10⁶ down to 10⁴ ml⁻¹, whereas nitrite oxidizers were less abundant (10³–10¹ order of magnitude). The results were in correspondence with the nitrite oxidation rate in the sludge types. As for the nirS, nirK, and nosZ gene copy numbers, their abundance was generally in the order of magnitude of 10⁸–10⁵. When sludge samples were subjected to lab-scale perturbations, a decrease in nitrification rate was reflected within 18 h in the copy numbers of nitrifier genes (decrease with 1 to 5 log units), whereas denitrification genes remained rather unaffected. These results demonstrate that the method is a fast and accurate tool for the analysis of the (de)nitrifying community structure and size in both natural and engineered environmental samples. Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.     

Enhancement of stress tolerance in transgenic tobacco plants constitutively expressing AtIpk2β, an inositol polyphosphate 6-/3-kinase from <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Inositol phosphates (IPs) and their turnover products have been implicated to play important roles in stress signaling in eukaryotic cells. In higher plants genes encoding inositol polyphosphate kinases have been identified previously, but their physiological functions have not been fully resolved. Here we expressed Arabidopsis inositol polyphosphate 6-/3-kinase (AtIpk2β) in two heterologous systems, i.e. the yeast Saccharomyces cerevisiae and in tobacco (Nicotiana tabacum), and tested the effect on abiotic stress tolerance. Expression of AtIpk2β rescued the salt-, osmotic- and temperature-sensitive growth defects of a yeast mutant strain (arg82Δ) that lacks inositol polyphosphate multikinase activity encoded by the ARG82/IPK2 gene. Transgenic tobacco plants constitutively expressing AtIpk2β under the control of the Cauliflower Mosaic Virus 35S promoter were generated and found to exhibit improved tolerance to diverse abiotic stresses when compared to wild type plants. Expression patterns of various stress responsive genes were enhanced, and the activities of anti-oxidative enzymes were elevated in transgenic plants, suggesting a possible involvement of AtIpk2β in plant stress responses. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.