A diffusible factor from arbuscular mycorrhizal fungi induces symbiosis-specific MtENOD11 expression in roots of Medicago truncatula

Using dual cultures of arbuscular mycorrhizal (AM) fungi and Medicago truncatula separated by a physical barrier, we demonstrate that hyphae from germinating spores produce a diffusible factor that is perceived by roots in the absence of direct physical contact. This AM factor elicits expression of the Nod factor-inducible gene MtENOD11, visualized using a pMtENOD11-gusA reporter. Transgene induction occurs primarily in the root cortex, with expression stretching from the zone of root hair emergence to the region of mature root hairs. All AM fungi tested (Gigaspora rosea, Gigaspora gigantea, Gigaspora margarita, and Glomus intraradices) elicit a similar response, whereas pathogenic fungi such as Phythophthora medicaginis, Phoma medicaginis var pinodella and Fusarium solani f.sp. phaseoli do not, suggesting that the observed root response is specific to AM fungi. Finally, pMtENOD11-gusA induction in response to the diffusible AM fungal factor is also observed with all three M. truncatula Nod(-)/Myc(-) mutants (dmi1, dmi2, and dmi3), whereas the same mutants are blocked in their response to Nod factor. This positive response of the Nod(-)/Myc(-) mutants to the diffusible AM fungal factor and the different cellular localization of pMtENOD11-gusA expression in response to Nod factor versus AM factor suggest that signal transduction occurs via different pathways and that expression of MtENOD11 is differently regulated by the two diffusible factors.     

Analysis of calcium spiking using a cameleon calcium sensor reveals that nodulation gene expression is regulated by calcium spike number and the developmental status of the cell

Rhizobium-made Nod factors induce rapid changes in both Ca(2+) and gene expression. Mutations and inhibitors that abolish Nod-factor-induced Ca(2+) spiking block gene induction, indicating a specific role for Ca(2+) spiking in signal transduction. We used transgenic Medicago truncatula expressing a "cameleon" Ca(2+) sensor to assess the relationship between Nod-factor-induced Ca(2+) spiking and the activation of downstream gene expression. In contrast to ENOD11 induction, Ca(2+) spiking is activated in all root-hair cells and in epidermal or pre-emergent root hairs cells in the root tip region. Furthermore, cortical cells immediately below the epidermal layer also show slow Ca(2+) spiking and these cells lack Nod-factor-induced ENOD11 expression. This indicates a specialization in nodulation gene induction downstream of Nod-factor perception and signal transduction. There was a gradient in the frequency of Ca(2+) spiking along the root, with younger root-hair cells having a longer period between spikes than older root hairs. Using a Ca(2+)-pump inhibitor to block Ca(2+) spiking at various times after addition of Nod factor, we conclude that about 36 consecutive Ca(2+) spikes are sufficient to induce ENOD11-GUS expression in root hairs. To determine if the length of time of Ca(2+) spiking or the number of Ca(2+) spikes is more critical for Nod-factor-induced ENOD11 expression, jasmonic acid (JA) was added to reduce the rate of Nod-factor-induced Ca(2+) spiking. This revealed that even when the period between Ca(2+) spikes was extended, an equivalent number of Ca(2+) spikes were required for the induction of ENOD11. However, this JA treatment did not affect the spatial patterning of ENOD11-GUS expression suggesting that although a minimal number of Ca(2+) spikes are required for Nod-factor-induced gene expression, other factors restrict the expression of ENOD11 to a subset of responding cells.     

Four genes of Medicago truncatula controlling components of a nod factor transduction pathway

Rhizobium nodulation (Nod) factors are lipo-chitooligosaccharides that act as symbiotic signals, eliciting several key developmental responses in the roots of legume hosts. Using nodulation-defective mutants of Medicago truncatula, we have started to dissect the genetic control of Nod factor transduction. Mutants in four genes (DMI1, DMI2, DMI3, and NSP) were pleiotropically affected in Nod factor responses, indicating that these genes are required for a Nod factor-activated signal transduction pathway that leads to symbiotic responses such as root hair deformations, expressions of nodulin genes, and cortical cell divisions. Mutant analysis also provides evidence that Nod factors have a dual effect on the growth of root hair: inhibition of endogenous (plant) tip growth, and elicitation of a novel tip growth dependent on (bacterial) Nod factors. dmi1, dmi2, and dmi3 mutants are also unable to establish a symbiotic association with endomycorrhizal fungi, indicating that there are at least three common steps to nodulation and endomycorrhization in M. truncatula and providing further evidence for a common signaling pathway between nodulation and mycorrhization.     

Evidence for structurally specific negative feedback in the Nod factor signal transduction pathway

Nod factor is a critical signalling molecule in the establishment of the legume/rhizobial symbiosis. The Nod factor of Sinorhizobium meliloti carries O-sulphate, O-acetate and C16:2 N-acyl attachments that define its activity and host specificity. Here we assess the relative importance of these modifications for the induction of calcium spiking in Medicago truncatula. We find that Nod factor structures lacking the O-sulphate, structures lacking the O-acetate and N-acyl groups, and structures lacking the O-acetate combined with a C18:1 N-acyl group all show calcium spiking when applied at high concentrations. These calcium responses are blocked in dmi1 and dmi2 mutants, suggesting that they function through the Nod factor signal transduction pathway. The dmi3 mutant, which is proposed to function in the Nod factor signal transduction pathway downstream of calcium spiking, shows increased sensitivity to Nod factor. This increased sensitivity is only active with wild-type Nod factor and was not present when the plants were treated with mutant Nod factor structures. We propose that the Nod factor signal transduction pathway is under negative feedback regulation that is activated at or downstream of DMI3 and requires structural components of the Nod factor molecule for activity.     

Calcium oscillations and Nod signal transduction in Rhizobium-legume symbiosis

Rhizobium nodulation (Nod) factors are lipo-chitooligosaccharides that act as symbiotic signals, eliciting a number of key developmental responses in the roots of legume hosts. One of the earliest responses of root hairs to Nod factors is the induction of sharp oscillations of cytoplasmic calcium ion concentration ("calcium spiking"). This response was first characterised in Medicago sativa and Nod factors were found to be unable to induce calcium spiking in a nodulation-defective mutant of M. sativa. The fact that this mutant lacked any morphological response to Nod factors raised the question of whether calcium spiking could be part of a Nod factor-induced signal transduction pathway leading to nodulation. More recently, calcium spiking has been described in a model legume, Medicago truncatula, and in pea. When nodulation-defective mutants were tested for the induction of calcium spiking in response to Nod factors, three loci of pea and two of M. truncatula were found to be necessary for Nod factor-induced calcium spiking. These loci are also known to be necessary for Nod factor-induction of symbiotic responses such as root hair deformation, nodulin gene expression and cortical cell division. These results therefore constitute strong genetic evidence for the role of calcium spiking in Nod factor transduction. This system provides an opportunity to use genetics to study ligand-stimulated calcium spiking as a signal transduction event.     

Expression of the Medicago truncatula DM12 gene suggests roles of the symbiotic nodulation receptor kinase in nodules and during early nodule development

The Medicago truncatula DMI2 gene encodes a receptorlike kinase required for establishing root endosymbioses. The DMI2 gene was shown to be expressed much more highly in roots and nodules than in leaves and stems. In roots, its expression was not altered by nitrogen starvation or treatment with lipochitooligosaccharidic Nod factors. Moreover, the DMI2 mRNA abundance in roots of the nfp, dmil, dmi3, nsp1, nsp2, and hcl symbiotic mutants was similar to the wild type, whereas lower levels in some dmi2 mutants could be explained by regulation by the nonsense-mediated decay, RNA surveillance mechanism. Using pDMI2::GUS fusions, the expression of DMI2 in roots appeared to be localized primarily in the cortical and epidermal cells of the younger, lateral roots and was not observed in the root apices. Following inoculation with Sinorhizobium meliloti, the DMI2 gene was induced in the nodule primordia, before penetration by the infection threads. No increased expression was seen in lateral-root primordia. In nodules, expression was observed primarily in a few cell layers of the pre-infection zone. These results are consistent with the DMI2 gene mediating Nod factor perception and transduction leading to rhizobial infection, not only in root epidermal cells but also during nodule development.     

Nod factor elicits two separable calcium responses in Medicago truncatula root hair cells

Modulation of intracellular calcium levels plays a key role in the transduction of many biological signals. Here, we characterize early calcium responses of wild-type and mutant Medicago truncatula plants to nodulation factors produced by the bacterial symbiont Sinorhizobium meliloti using a dual-dye ratiometric imaging technique. When presented with 1 nM Nod factor, root hair cells exhibited only the previously described calcium spiking response initiating 10 min after application. Nod factor (10 nM) elicited an immediate increase in calcium levels that was temporally earlier and spatially distinct from calcium spikes occurring later in the same cell. Nod factor analogs that were structurally related, applied at 10 nM, failed to initiate this calcium flux response. Cells induced to spike with low Nod factor concentrations show a calcium flux response when Nod factor is raised from 1 to 10 nM. Plant mutants previously shown to be deficient for the calcium spiking response (dmi1 and dmi2) exhibited an immediate, truncated calcium flux with 10 nM Nod factor, demonstrating a competence to respond to Nod factor but an impaired ability to generate a full biphasic response. These results demonstrate that the legume root hair cell exhibits two independent calcium responses to Nod factor triggered at different agonist concentrations and suggests an early branch point in the Nod factor signal transduction pathway.     

The DMI1 and DMI2 early symbiotic genes of medicago truncatula are required for a high-affinity nodulation factor-binding site associated to a particulate fraction of roots

The establishment of the legume-rhizobia symbiosis between Medicago spp. and Sinorhizobium meliloti is dependent on the production of sulfated lipo-chitooligosaccharidic nodulation (Nod) factors by the bacterial partner. In this article, using a biochemical approach to characterize putative Nod factor receptors in the plant host, we describe a high-affinity binding site (Kd = 0.45 nm) for the major Nod factor produced by S. meliloti. This site is termed Nod factor-binding site 3 (NFBS3). NFBS3 is associated to a high-density fraction prepared from roots of Medicago truncatula and shows binding specificity for lipo-chitooligosaccharidic structures. As for the previously characterized binding sites (NFBS1 and NFBS2), NFBS3 does not recognize the sulfate group on the S. meliloti Nod factor. Studies of Nod factor binding in root extracts of early symbiotic mutants of M. truncatula reveals that the new site is present in Nod factor perception and does not make infections 3 (dmi3) mutants but is absent in dmi1 and dmi2 mutants. Roots and cell cultures of all these mutants still contain sites similar to NFBS1 and NFBS2, respectively. These results suggest that NFBS3 is different from NFBS2 and NFBS1 and is dependent on the common symbiotic genes DMI1 and DMI2 required for establishment of symbioses with both rhizobia and arbuscular mycorrhizal fungi. The potential role of this site in the establishment of root endosymbioses is discussed.     

Rhizobial lipochitooligosaccharide nodulation factors activate expression of the legume early nodulin gene ENOD12 in rice

Lipochitooligosaccharide nodulation factors (Nod factors) produced by rhizobia are a major host range determinant. These factors play a pivotal role in the molecular signal exchange, infection and induction of symbiotic developmental responses in legumes leading to the formation of a nodule in which rhizobia carry out N₂ fixation. Determining whether rice ( Oryza sativa ) can respond to Nod factors could lead to strategies that would make rice amenable to develop a nitrogen-fixing endosymbiotic association with rhizobia. We introduced into rice the promoter of the infection-related gene MtENOD12 (from Medicago truncatula ) fused to the β-glucuronidase (GUS) reporter gene to serve as a molecular marker to aid in the detection of Nod factor signal perception by rice cells. Treatment of the transgenic rice roots with Nod factors (10^–6–10^–9 m ) under nitrogen-limiting conditions induced MtENOD12 -GUS expression in cortical parenchyma, endodermis and pericycle. In contrast, chitooligosaccharide backbone alone failed to elicit such a response in the root tissues. These findings demonstrate that rice roots perceive Nod factors and that these lipochitooligosaccharides, but not simple chitin oligomers, act as signal molecules in activating MtENOD12 in cortical parenchyma as in legumes. Exogenous application of N -naphthaleneacetic acid mimicked the Nod factor-elicited tissue-specific expression of MtENOD12 in roots while cytokinins inhibited it, thus evidencing that Nod factors, auxin and cytokinins probably act on similar signaling elements responsible for the regulation of MtENOD12 activation in rice. Taken together, these results suggest that at least a portion of the signal transduction machinery important for legume nodulation is likely to exist in rice.      

Nod factor-induced root hair curling: continuous polar growth towards the point of nod factor application

A critical step in establishing a successful nitrogen-fixing symbiosis between rhizobia and legume plants is the entrapment of the bacteria between root hair cell walls, usually in characteristic 180 degrees to 360 degrees curls, shepherd's crooks, which are formed by the host's root hairs. Purified bacterial signal molecules, the nodulation factors (NFs), which are lipochitooligosaccharides, induce root hair deformation in the appropriate host legume and have been proposed to be a key player in eliciting root hair curling. However, for curling to occur, the presence of intact bacteria is thought to be essential. Here, we show that, when spot applied to one side of the growing Medicago truncatula root hair tip, purified NF alone is sufficient to induce reorientation of the root hair growth direction, or a full curl. Using wild-type M. truncatula containing the pMtENOD11::GUS construct, we demonstrate that MtENOD11::GUS is expressed after spot application. The data have been incorporated into a cell biological model, which explains the formation of shepherd's crook curls around NF-secreting rhizobia by continuous tip growth reorientation.     

Mastoparan activates calcium spiking analogous to Nod factor-induced responses in Medicago truncatula root hair cells

The rhizobial-derived signaling molecule Nod factor is essential for the establishment of the Medicago truncatula/Sinorhizobium meliloti symbiosis. Nod factor perception and signal transduction in the plant involve calcium spiking and lead to the induction of nodulation gene expression. It has previously been shown that the heterotrimeric G-protein agonist mastoparan can activate nodulation gene expression in a manner analogous to Nod factor activation of these genes and this requires DOESN'T MAKE INFECTIONS3 (DMI3), a calcium- and calmodulin-dependent protein kinase (CCaMK) that is required for Nod factor signaling. Here we show that mastoparan activates oscillations in cytosolic calcium similar but not identical to Nod factor-induced calcium spiking. Mastoparan-induced calcium changes occur throughout the cell, whereas Nod factor-induced changes are restricted to the region associated with the nucleus. Mastoparan-induced calcium spiking occurs in plants mutated in the receptor-like kinases NOD FACTOR PERCEPTION and DMI2 and in the putative cation channel DMI1, which are all required for Nod factor induction of calcium spiking, indicating either that mastoparan functions downstream of these components or that it uses an alternative mechanism to Nod factor for activation of calcium spiking. However, both mastoparan and Nod factor-induced calcium spiking are inhibited by cyclopiazonic acid and n-butanol, suggesting some common mechanisms underpinning these two calcium agonists. The fact that mastoparan and Nod factor both activate calcium spiking and can induce nodulation gene expression in a DMI3-dependent manner strongly implicates CCaMK in the perception and transduction of the calcium signal.     

Time Course of Cell Biological Events Evoked in Legume Root Hairs by Rhizobium Nod Factors: State of the Art

In many common legumes, when host-specific nodule bacteria meettheir legume root they attach to it and enter through root hairs.The bacteria can intrude these cells because they instigatein the hairs the formation of an inward growing tube, the infectionthread, which consists of wall material. Prior to infectionthread formation, the bacteria exploit the cell machinery forwall deposition by inducing the hairs to form a curl, in whichthe dividing bacteria become entrapped. In most species, Nodfactor alone (a lipochito-oligosaccharide excreted by bacteria)induces root hair deformation, though without curling, thusmost aspects of the initial effects of Nod factor can be elucidatedby studying root hair deformation. In this review we discussthe cellular events that host-specific Nod factors induce intheir host legume root hairs. The first event, detectable onlya few seconds after Nod factor application, is a Ca²⁺influxat the root hair tip, followed by a transient depolarizationof the plasma membrane potential, causing an increase in cytosolic[Ca²⁺] at the root hair tip. Also within minutes, Nod factorschange the cell organization by acting on the actin cytoskeleton,enhancing tip cell wall deposition so that root hairs becomelonger than normal for their species. Since the remodellingof the actin cytoskeleton precedes the second calcium event,Ca²⁺spiking, which is observed in the perinuclear area, we proposethat the initial cytoskeleton events taking place at the hairtip are related to Ca²⁺influx in the hair tip and that Ca²⁺spikingserves later events involving gene expression. Copyright 2001Annals of Botany Company Review, Nod factor, tip growth, root hair, Rhizobium, legume, cytoskeleton, calcium, symbiosis     

Genetic and cytogenetic mapping of DMI1, DMI2, and DMI3 genes of Medicago truncatula involved in Nod factor transduction,nodulation, and mycorrhization

The DMI1, DMI2, and DMI3 genes of Medicago truncatula, which are required for both nodulation and mycorrhization, control early steps of Nod factor signal transduction. Here, we have used diverse approaches to pave the way for the map-based cloning of these genes. Molecular amplification fragment length polymorphism markers linked to the three genes were identified by bulked segregant analysis. Integration of these markers into the general genetic map of M. truncatula revealed that DMI1, DMI2, and DMI3 are located on linkage groups 2, 5, and 8, respectively. Cytogenetic studies using fluorescent in situ hybridization (FISH) on mitotic and pachytene chromosomes confirmed the location of DMI1, DMI2, and DMI3 on chromosomes 2, 5, and 8. FISH-pachytene studies revealed that the three genes are in euchromatic regions of the genome, with a ratio of genetic to cytogenetic distances between 0.8 and 1.6 cM per microm in the DMI1, DMI2, and DMI3 regions. Through grafting experiments, we showed that the genetic control of the dmi1, dmi2, and dmi3 nodulation phenotypes is determined at the root level. This means that mutants can be transformed by Agrobacterium rhizogenes to accelerate the complementation step of map-based cloning projects for DMI1, DMI2, and DMI3.     

Arbuscular mycorrhizal hyphopodia and germinated spore exudates trigger Ca2+ spiking in the legume and nonlegume root epidermis

? The aim of this study was to investigate Ca(2+) responses to endosymbiotic arbuscular mycorrhizal (AM) fungi in the host root epidermis following pre-infection hyphopodium formation in both legumes and nonlegumes, and to determine to what extent these responses could be mimicked by germinated fungal spore exudate. ? Root organ cultures of both Medicago truncatula and Daucus carota, expressing the nuclear-localized cameleon reporter NupYC2.1, were used to monitor AM-elicited Ca(2+) responses in host root tissues. ? Ca(2+) spiking was observed in cells contacted by AM hyphopodia for both hosts, with highest frequencies correlating with the epidermal nucleus positioned facing the fungal contact site. Treatment with AM spore exudate also elicited Ca(2+) spiking within the AM-responsive zone of the root and, in both cases, spiking was dependent on the M. truncatula common SYM genes DMI1/2, but not on the rhizobial Nod factor perception gene NFP. ? These findings support the conclusion that AM fungal root penetration is preceded by a SYM pathway-dependent oscillatory Ca(2+) response, whose evolutionary origin predates the divergence between asterid and rosid clades. Our results further show that fungal symbiotic signals are already generated during spore germination, and that cameleon-expressing root organ cultures represent a novel AM-specific bio-assay for such signals.     

Identification and characterization of nodulation-signaling pathway 2, a gene of Medicago truncatula involved in Nod actor signaling

Bacterially derived Nod factor is critical in the establishment of the legume/rhizobia symbiosis. Understanding the mechanisms of Nod factor perception and signal transduction in the plant will greatly advance our understanding of this complex interaction. Here, we describe the identification of a new locus, nodulation-signaling pathway 2 (NSP2), of Medicago truncatula that is involved in Nod factor signaling. Mutants at this locus are blocked for Nod factor-induced gene expression and show a reduced root hair deformation response. nsp2 plants also show a complete absence of infection and cortical cell division following Sinorhizobium meliloti inoculation. Nod factor-induced calcium spiking, one of the earliest responses tested, is still functional in these mutant plants. We conclude that the gene NSP2 is a component of the Nod factor signal transduction pathway that lies downstream of the calcium-spiking response.     

Agrobacterium rhizogenes-transformed roots of Medicago truncatula for the study of nitrogen-fixing and endomycorrhizal symbiotic associations

Medicago truncatula, a diploid autogamous legume, is currently being developed as a model plant for the study of root endosymbiotic associations, including nodulation and mycorrhizal colonization. An important requirement for such a plant is the possibility of rapidly introducing and analyzing chimeric gene constructs in root tissues. For this reason, we developed and optimized a convenient protocol for Agrobacterium rhizogenes-mediated transformation of M. truncatula. This unusual protocol, which involves the inoculation of sectioned seedling radicles, results in rapid and efficient hairy root organogenesis and the subsequent development of vigorous "composite plants." In addition, we found that kanamycin can be used to select for the cotransformation of hairy roots directly with gene constructs of interest. M. truncatula composite plant hairy roots have a similar morphology to normal roots and can be nodulated successfully by their nitrogen-fixing symbiotic partner, Sinorhizobium meliloti. Furthermore, spatiotemporal expression of the Nod factor-responsive reporter pMtENOD11-gusA in hairy root epidermal tissues is indistinguishable from that observed in Agrobacterium tumefaciens-transformed lines. M. truncatula hairy root explants can be propagated in vitro, and we demonstrate that these clonal lines can be colonized by endomycorrhizal fungi such as Glomus intraradices with the formation of arbuscules within cortical cells. Our results suggest that M. truncatula hairy roots represent a particularly attractive system with which to study endosymbiotic associations in transgenically modified roots.     

Pharmacological analysis of nod factor-induced calcium spiking in Medicago truncatula. Evidence for the requirement of type IIA calcium pumps and phosphoinositide signaling

Bacterial Nod factors trigger a number of cellular responses in root hairs of compatible legume hosts, which include periodic, transient increases in cytosolic calcium levels, termed calcium spiking. We screened 13 pharmaceutical modulators of eukaryotic signal transduction for effects on Nod factor-induced calcium spiking. The purpose of this screening was 2-fold: to implicate enzymes required for Nod factor-induced calcium spiking in Medicago sp., and to identify inhibitors of calcium spiking suitable for correlating calcium spiking to other Nod factor responses to begin to understand the function of calcium spiking in Nod factor signal transduction. 2-Aminoethoxydiphenylborate, caffeine, cyclopiazonic acid (CPA), 2,5-di-(t-butyl)-1,4-hydroquinone, and U-73122 inhibit Nod factor-induced calcium spiking. CPA and U-73122 are inhibitors of plant type IIA calcium pumps and phospholipase C, respectively, and implicate the requirement for these enzymes in Nod factor-induced calcium spiking. CPA and U-73122 inhibit Nod factor-induced calcium spiking robustly at concentrations with no apparent toxicity to root hairs, making CPA and U-73122 suitable for testing whether calcium spiking is causal to subsequent Nod factor responses.     

Nod factors and a diffusible factor from arbuscular mycorrhizal fungi stimulate lateral root formation in Medicago truncatula via the DMI1/DMI2 signalling pathway

Legumes form two different types of intracellular root symbioses, with fungi and bacteria, resulting in arbuscular mycorrhiza and nitrogen-fixing nodules, respectively. Rhizobial signalling molecules, called Nod factors, play a key role in establishing the rhizobium-legume association and genes have been identified in Medicago truncatula that control a Nod factor signalling pathway leading to nodulation. Three of these genes, the so-called DMI1, DMI2 and DMI3 genes, are also required for formation of mycorrhiza, indicating that the symbiotic pathways activated by both the bacterial and the fungal symbionts share common steps. To analyse possible cross-talk between these pathways we have studied the effect of treatment with Nod factors on mycorrhization in M. truncatula. We show that Nod factors increase mycorrhizal colonization and stimulate lateral root formation. The stimulation of lateral root formation by Nod factors requires both the same structural features of Nod factors and the same plant genes (NFP, DMI1, DMI2, DMI3 and NSP1) that are required for other Nod factor-induced symbiotic responses such as early nodulin gene induction and cortical cell division. A diffusible factor from arbuscular mycorrhizal fungi was also found to stimulate lateral root formation, while three root pathogens did not have the same effect. Lateral root formation induced by fungal signal(s) was found to require the DMI1 and DMI2 genes, but not DMI3. The idea that this diffusible fungal factor might correspond to a previously hypothesized mycorrhizal signal, the 'Myc factor', is discussed.