Root Hair Deformation Research Articles

Nod factor structures, responses, and perception during initiation of nodule development.

The onset of nodule development, the result of rhizobia-legume symbioses, is determined by the exchange of chemical compounds between microsymbiont and leguminous host plant. Lipo-chitooligosaccharidic nodulation (Nod) factors, secreted by rhizobia, belong to these signal molecules. Nod factors consist of an acylated chitin oligomeric backbone with various substitutions at the (non)reducing-terminal and/or nonterminal residues. They induce the formation and deformation of root hairs, intra- and extracellular alkalinization, membrane potential depolarization, changes in ion fluxes, early nodulin gene expression, and formation of nodule primordia. Nod factors play a key role during nodule initiation and act at nano- to picomolar concentrations. A correct chemical structure is required for induction of a particular plant response, suggesting that Nod factor-receptor interaction(s) precede(s) a Nod factor-induced signal transduction cascade. Current data on Nod factor structures and Nod factor-induced responses are highlighted as well as recent advances in the characterization of proteins, possibly involved in recognition of Nod factors by the host plant.

Nod factors stimulate plasma membrane delimited phospholipase C activity in vitro

Nod factors are lipo‐chito‐oligosaccharides secreted by Rhizobium to initiate deformation of root hairs and other changes in host plants. Since Nod factor‐induced changes in intracellular calcium occur in responsive root hairs, we tested if phospholipase C (PLC) activity is stimulated by Nod factors. Plasma membranes were isolated from the nodulation‐competent zone of roots of Vigna unguiculata to assay PLC activity in vitro. Nod factors isolated from Rhizobium sp. NGR234, NodNGR[S] and NodNGR[Ac] significantly increased PLC activity and this increase in activity was inhibited in the presence of the PLC inhibitors, neomycin and U‐73122. The response appears specific as PLC activity was not significantly induced neither by the 4‐sugar, N,N′,N′′,N′′′‐tetracetylchitotetraose (TACT), or the five‐sugar, penta‐N‐acetylchitopentaose (PACT), backbone of Nod factors. The G‐protein activators, GTPγS and the aluminium fluoride complex, had no effect on PLC activity in the presence or absence of NodNGR[S], suggesting that Nod factors act independently of G‐proteins in vitro. However, the combination of oleic acid and TACT mimicked the effect of Nod factors on PLC activity indicating that the presence of the lipid tail may be critical. Also this combination of compounds acted synergistically together to evoke root hair deformation in vivo. Our results indicate that Nod factors can modulate membrane delimited PLC activity and indicate that PLC is likely to be a component of the Nod factor‐signalling pathway.

Responses of a model legume Lotus japonicus to lipochitin oligosaccharide nodulation factors purified from Mesorhizobium loti JRL501.

Lotus japonicus has been proposed as a model legume for molecular genetic studies of symbiotic plant-microbe interactions leading to the fixation of atmospheric nitrogen. Lipochitin oligosaccharides (LCOs), or Nod factors, were isolated from the culture of Mesorhizobium loti strain JRL501 (MAFF303099), an efficient microsymbiont of L. japonicus B-129 cv. Gifu. High-performance liquid chromatography and mass spectrometric analyses allowed us to identify at least five different structures of LCOs that were produced by JRL501. The major component was NodMl-V(C18:1, Me, Cb, AcFuc), an N-acetyl-glucosamine pentamer in which the nonreducing residue is N-acylated with a C18:1 acyl moiety, N-methylated, and carries a carbamoyl group and the reducing N-acetylglucosamine residue is substituted with 4-O-acetyl-fucose. Additional novel LCO structures bearing fucose instead of acetyl-fucose at the reducing end were identified. Mixtures of these LCOs could elicit abundant root hair deformation on L. japonicus roots at a concentration of 10(-7) to 10(-9) M. Spot inoculation of a few nanograms of LCOs on L. japonicus roots induced the formation of nodule primordia in which the early nodulin genes, ENOD40 and ENOD2, were expressed in a tissue-specific manner. We also observed the formation of a cytoplasmic bridge (preinfection thread) in the swollen outermost cortical cells. This is the first description of cytoplasmic bridge formation by purified LCOs alone in a legume-forming determinate nodules.

Novel infection process in the indeterminate root nodule symbiosis between Chamaecytisus proliferus (tagasaste) and Bradyrhizobium sp.

Summary The main characteristics of the symbiosis of tagasaste (Chamaecytisus proliferus ssp. proliferus var. palmensis), a woody legume forming N2‐fixing indeterminate nodules in response to infection by strains of Bradyrhizobium sp. (Chamaecytisus), are reported here. The infection process in this legume was examined by bright field, phase contrast and transmission electron microscopy, and was found to be unlike any other previously described. First steps in the infection process involve initiation of infection threads within deformed root hairs and induction of foci of host‐cell divisions in the inner root cortex. However, infection of root hairs aborts early, and instead, the bacteria use the crack‐entry mode of host infection, whereby they penetrate the periphery of the emerging nodule through an intercellular route, eventually infecting host nodule cells directly through altered cell walls. No successful infection threads were detected at any stage of primary‐host infection or nodule invasion. Indeterminate nodules were mainly formed on unbranched areas of lateral roots. This is the first description of such a combination of events in an infection process in the Rhizobium–legume root‐nodule symbiosis.

The HCL gene of Medicago truncatula controls Rhizobium-induced root hair curling.

The symbiotic infection of the model legume Medicago truncatula by Sinorhizobium meliloti involves marked root hair curling, a stage where entrapment of the microsymbiont occurs in a chamber from which infection thread formation is initiated within the root hair. We have genetically dissected these early symbiotic interactions using both plant and rhizobial mutants and have identified a M. truncatula gene, HCL, which controls root hair curling. S. meliloti Nod factors, which are required for the infection process, induced wild-type epidermal nodulin gene expression and root hair deformation in hcl mutants, while Nod factor induction of cortical cell division foci was reduced compared to wild-type plants. Studies of the position of nuclei and of the microtubule cytoskeleton network of hcl mutants revealed that root hair, as well as cortical cells, were activated in response to S. meliloti. However, the asymmetric microtubule network that is typical of curled root hairs, did not form in the mutants, and activated cortical cells did not become polarised and did not exhibit the microtubular cytoplasmic bridges characteristic of the pre-infection threads induced by rhizobia in M. truncatula. These data suggest that hcl mutations alter the formation of signalling centres that normally provide positional information for the reorganisation of the microtubular cytoskeleton in epidermal and cortical cells.

Cloning and expression of a down-regulated gene (TrEnodDR1) of white clover responded by the nod genes derived from Rhizobiumleguminosarum bv. trifolii strain 4S

The nodulation genes of Rhizobiumleguminosarum bv. trifolii 4S (strain 4S) were cloned into cosmid vector pLAFR1 named pC4S8 which was contained nodNMLFEDABCIJ and a part of nodT as an insert. The pC4S8 was transferred to strain H1, Sym plasmid (pRt4Sa) cured strain of strain 4S, and isolated as Tc resistant and nodulation restored mutant, strain H1(pC4S8). During infection process of this strain, visible symbiotic features, such as root hair curling (Hac), root hair deformation (Had) and infection thread formation (Inf) were also restored. The nodule forming ability of strain H1(pC4S8) was increased 3–4 times in nodule number than that of strain 4S. Then, to investigate the effect of Rhizobiumnod genes on the host plant (Trifoliumrepens L.) gene expression, cDNAs which were responded to the inoculation of rhizobia were differentially screened based on the presence or absence of nod genes treated with strains H1(pC4S8) or H1, respectively. The cDNA, TrEnodDR1 (Trifoliumrepensearlynodulindownregulation1) gene was isolated from cDNA library prepared from white clover seedlings treated with nod− strain H1, but didn't exhibit in nod+ treated cDNA library, as a down-regulated gene. Expression analysis of TrEnodDR1 was performed in various tissues of white clover, it is suppressed in root nodule and also strongly suppressed by the inoculation of rhizobia in the seedlings. It is discussed that TrEnodDR1 gene is suppressed when the white clover comes into symbiosis with rhizobia.

Nod factor-induced phosphatidic acid and diacylglycerol pyrophosphate formation: a role for phospholipase C and D in root hair deformation.

Rhizobium-secreted nodulation factors are lipochitooligosaccharides that trigger the initiation of nodule formation on host legume roots. The first visible effect is root hair deformation, but the perception and signalling mechanisms that lead to this response are still unclear. When we treated Vicia sativa seedlings with mastoparan root hairs deformed, suggesting that G proteins are involved. To investigate whether mastoparan and Nod factor activate lipid signalling pathways initiated by phospholipase C (PLC) and D (PLD), seedlings were radiolabelled with [(32)P]orthophosphate prior to treatment. Mastoparan stimulated increases in phosphatidic acid (PA) and diacylglycerol pyrophosphate, indicative of PLD or PLC activity in combination with diacylglycerol kinase (DGK) and PA kinase. Treatment with Nod factor had similar effects, although less pronounced. The inactive mastoparan analogue Mas17 had no effect. The increase in PA was partially caused by the activation of PLD that was monitored by its in vivo transphosphatidylation activity. The application of primary butyl alcohols, inhibitors of PLD activity, blocked root hair deformation. Using different labelling strategies, evidence was provided for the activation of DGK. Since the PLC antagonist neomycin inhibited root hair deformation and the formation of PA, we propose that PLC activation produced diacylglycerol (DAG), which was subsequently converted to PA by DGK. The roles of PLC and PLD in Nod factor signalling are discussed.

Nod factor‐induced phosphatidic acid and diacylglycerol pyrophosphate formation: a role for phospholipase C and D in root hair deformation

SummaryRhizobium‐secreted nodulation factors are lipochitooligosaccharides that trigger the initiation of nodule formation on host legume roots. The first visible effect is root hair deformation, but the perception and signalling mechanisms that lead to this response are still unclear. When we treated Vicia sativa seedlings with mastoparan root hairs deformed, suggesting that G proteins are involved. To investigate whether mastoparan and Nod factor activate lipid signalling pathways initiated by phospholipase C (PLC) and D (PLD), seedlings were radiolabelled with [32P]orthophosphate prior to treatment. Mastoparan stimulated increases in phosphatidic acid (PA) and diacylglycerol pyrophosphate, indicative of PLD or PLC activity in combination with diacylglycerol kinase (DGK) and PA kinase. Treatment with Nod factor had similar effects, although less pronounced. The inactive mastoparan analogue Mas17 had no effect. The increase in PA was partially caused by the activation of PLD that was monitored by its in vivo transphosphatidylation activity. The application of primary butyl alcohols, inhibitors of PLD activity, blocked root hair deformation. Using different labelling strategies, evidence was provided for the activation of DGK. Since the PLC antagonist neomycin inhibited root hair deformation and the formation of PA, we propose that PLC activation produced diacylglycerol (DAG), which was subsequently converted to PA by DGK. The roles of PLC and PLD in Nod factor signalling are discussed.

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.

Azospirillum brasilense colonisation of wheat roots and the role of lectin–carbohydrate interactions in bacterial adsorption and root-hair deformation

The dynamics of adsorption of the nitrogen-fixing soil bacteria Azospirillum brasilense 75 and 80 (isolated from soil samples collected in Saratov Oblast, southern Russia) and A. brasilense Sp245 to the roots of seedlings of common spring wheat was studied in relation to inoculum size, period of incubation with the roots and bacterial-growth phase. The number of root-attached cells increased with increasing size of inoculum and time of contact. The saturation of root-surface adsorption was observed by 24 h of co-incubation for A. brasilense 75, by 6 h for A. brasilense 80, and by 3 h for A. brasilense Sp245. The firmness of bacterial–root attachment increased after extended co-incubation. Differences in the adsorption kinetics of the azospirilla were found that were associated with bacterial-growth phases. Azospirilla attached to the roots of their host cultivar more actively than they did to the roots of a non-host cultivar. Adsorption was partially inhibited when the roots were treated with N-acetyl-D-glucosamine. Maximal inhibition occurred after a 3-h exposure of the roots to the bacteria. Root-hair deformation induced with polysaccharide-containing complexes from the Azospirillum capsular material was inhibited by N-acetyl-D-glucosamine and chitotriose, specific haptens of wheat germ agglutinin. A possible mechanism of the mutual influence of bacteria and plants may involve key roles of wheat germ agglutinin, present on the roots, and the polysaccharide-containing components of the Azospirillum capsule.

Evidence for the production of chemical compounds analogous to nod factor by the silicate bacterium Bacillus circulans GY92

Silicate bacteria are generally placed in the species Bacillus circulans and are widely used in biological fertilisers and biological leaching. The bacteria can form conspicuous amounts of extracellular polysaccharides in nitrogen-free media or in the presence of substrates with large C/N ratios. Using high performance liquid chromatography, we have shown that B. circulans produced a new peak/compound when induced with the plant-to-bacteria signal molecule genistein. This material co-eluted with the lipo-chitooligosaccharide (Nod Bj-V (C18:1, MeFuc)) of Bradyrhizobium japonicum. This compound exhibited root hair deformation activity on soybean, which is characteristic of lipo-chitooligosaccharides (LCOs). We propose that this might be an LCO or closely related compound with similar biological activity.

Early symbiotic responses induced by Sinorhizobium meliloti iIvC mutants in alfalfa.

A mutation in the ilvC gene of Sinorhizobium meliloti 1021 determines a symbiotically defective phenotype. ilvC mutants obtained from different S. meliloti wild-type strains are able to induce root hair deformation on alfalfa roots and show variable activation of the common nodulation genes nodABC. All of these mutants are noninfective. The presence of extra copies of nodD3-syrM in an IlvC- background does not promote nod expression but allows the detection of low levels of Nod factor production. The sulphation of the Nod factor metabolites, however, is not affected. Furthermore, IlvC- strains induce a specific pattern of starch accumulation on alfalfa roots as well as of early nodulin expression. Hence, the pleiotropic action of the ilvC gene in S. meliloti may reveal novel complexities involved in the symbiotic interaction.

Deleterious properties of certain rhizosphere bacteria on field pea ( Pisum sativum) under gnotobiotic and non-sterile conditions

Three strains of Pseudomonas putida, one non-fluorescent and two fluorescent, were investigated in a series of complementary experiments to characterise their inhibitory effects on peas under different environmental conditions. Firstly, a gnotobiotic growth pouch system was developed to observe the deleterious effects of the strains on pea root development. A negative impact of the strains was observed on the development of the root morphology using these pouches which was accompanied with a subsequent reduction in root biomass. By using this method it was concluded that the deleterious effect of one of the strains was dependent on the inoculum density. Secondly, two complementary studies in non-sterile growth systems where pea seeds/seedlings were inoculated with the bacteria, showed deleterious effects on plant biomass by two of the strains. Thirdly, by using a sterile plant growth system allowing microscopic observations on root hair development, all strains were found to be able to induce root hair deformations on pea seedlings. The results showed that the mode of action for the deleterious effect differ between the strains. Based on our findings, we would like to emphasise the necessity to include a palette of different sterile and non-sterile growth systems to be able to identify characteristics of importance for deleterious rhizosphere bacteria.

Differential response of soybean (Glycine max (L.) Merr.) genotypes to lipo-chito-oligosaccharide Nod Bj V (C(18:1) MeFuc).

Lipo-chito-oligosaccharides (LCOs) are bacteria-to-plant signal molecules essential for the establishment of rhizobia-legume symbioses. LCOs invoke a number of physiological changes in the host plants, such as root hair deformation, cortical cell division and ontogeny of complete nodule structures. The responses of five soybean cultivars to Nod BJ: V (C(18:1) MeFuc) isolated from Bradyrhizobium japonicum strain 532C were studied with a new technique. Two distinct types of root hair deformation were evident (i) bulging, in which root hairs were swollen at the tip or at the base depending on the cultivars and (ii) curling. The nodulating capacity of B. japonicum 532C varied among cultivars. Cultivars that produced a bulging reaction when treated with LCO had fewer nodules and the roots had low phenol contents. Cultivars that produced curling had higher numbers of nodules and the roots had higher amounts of phenol. Further, the roots of cultivars that showed root hair bulging were able to degrade LCO much faster than cultivars that manifested curling. The results of the present study establish relationships among the type of LCO-induced root hair deformation, root system LCO-degrading ability and nodulation capacity of soybean cultivars.

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.

In vivo fluorescence correlation microscopy (FCM) reveals accumulation and immobilization of Nod factors in root hair cell walls.

Fluorescence correlation microscopy (FCM) is a new single-molecule detection technique based on the confocal principle to quantify molecular diffusion and concentration of fluorescent molecules (particles) with sub-micron resolution. In this study, FCM is applied to examine the diffusional behaviour of fluorescent Nod factor analogues on living Vicia sativa root hairs. Three recently described Nod factors with a fluorescent acyl chain (Goedhart et al. Biochemistry 1999, 38, 10898-10907) were used. Plasmolysis of fluorescently labelled root hairs showed that the Nod factors are predominantly located in the cell wall, as hardly any fluorescence could be detected in the plasma membrane. After Nod factor-induced root hair deformation, the new outgrowth was not labelled, indicating a lack of migration of Nod factors to the newly synthesized cell wall. In agreement, FCM showed a > 1,000-fold reduction of molecular mobility of the fluorescence Nod factors upon binding to the cell wall. In addition, FCM demonstrated that Nod factors, when exogenously applied in aqueous solution at 10 nM, markedly concentrate in the cell wall of root hairs (up to 50-fold). The feasibility of applying FCM for the study of living plant cells as well as the implications of our results for the perception of Nod factors are discussed.

Investigation of the initial stages of interaction of the bacteriumAzospirillum brasilense with wheat seedling roots: Adsorption and root hair deformation

The initial stages of colonization of wheat roots by cells ofAzospirillum brasilense strains 75 and 80 isolated from soils of the Saratov oblast were studied. The adsorption of azospirilla on root hairs of soft spring wheats rapidly increased in the first hours of incubation, going then to a plateau phase. Within the first 15 h of incubation, exponential-phase cells were adsorbed more intensively than stationary-phase cells. Conversely, stationary-phase cells were adsorbed more intensively than exponential-phase cells, if the period of azospirilla incubation with the wheat roots was extended. As the time of incubation increased, the attachment of azospirilla to the wheat roots became stronger. The effect of cell attachment to root hairs was strain-dependent; the number of adsorbed cells of a given strain of azospirilla was greater in the case of host wheat cultivars. The deformation of wheat root hairs was affected by the polysaccharide-containing complexes isolated from the capsular material of azospirilla. The suggestion is made that common receptor systems are involved in the adsorption of azospirilla on roots and in root hair deformation

N-deacetylation of Sinorhizobium meliloti Nod factors increases their stability in the Medicago sativa rhizosphere and decreases their biological activity.

Nod factors excreted by rhizobia are signal molecules that consist of a chitin oligomer backbone linked with a fatty acid at the nonreducing end. Modifications of the Nod factor structures influence their stability in the rhizosphere and their biological activity. To test the function of N-acetyl groups in Nod factors, NodSm-IV(C16:2,S) from Sinorhizobium meliloti was enzymatically N-deacetylated in vitro with purified chitin deacetylase from Colletotrichum lindemuthianum. A family of partially and completely deacetylated derivatives was produced and purified. The most abundant chemical structures identified by mass spectrometry were GlcN(C16:2)-GlcNAc-GlcNH2-GlcNAc(OH)(S), GlcN(C16,2)-GlcNAc-GlcNH2-GlcNH2(OH)(S), and GlcN(C16:2)-GlcNH2-GlcNH2-GlcNH2(OH)(S). In contrast to NodSm-IV(C16:2,S), the purified N-deacetylated derivatives were stable in the rhizosphere of Medicago sativa, indicating that the N-acetyl groups make the carbohydrate moiety of Nod factors accessible for glycosyl hydrolases of the host plant. The N-deacetylated derivatives displayed only a low level of activity in inducing root hair deformation. Furthermore, the N-deacetylated molecules were not able to stimulate Nod factor degradation by M. sativa roots, a response elicited by active Nod factors. These data show that N-acetyl groups of Nod factors are required for biological activity.

Structural and functional comparison of Frankia root hair deforming factor and rhizobia Nod factor

The infectious processes of the Frankia-Alnus and Rhizobium-legume symbioses present strong similarities, suggesting the existence of analogies between Frankia root hair deforming factor and rhizobia Nod factors. Biochemical and functional analogies were tested using ACoN24d Frankia strain. The putative chitin-like nature of the Frankia deforming factor was explored by (i) gas chromatography coupled to mass spectrometry and thin layer chromatography, after radioactive labeling of the culture for detection of chitin oligomers, and (ii) following the root hair deforming activity of the supernatant after discriminating treatments (temperature, chitinase, butanol extraction). In parallel, the functional analogy was questioned by testing the mitotic activity of the Frankia supernatant onAlnus glutinosa (L.) roots. The implication in the symbiotic process of the Frankia factor was indirectly explored by testing the effect of a nodulation inhibitor (combined nitrogen) on root hair deformation. The studies of the combined nitrogen effect on root hair deformation indicate that the deformation induced in vitro by the Frankia factor is linked to the symbiotic process. Moreover, the various approaches used suggest that rhizobia Nod factors and Frankia root hair deforming factor are two structurally divergent symbiotic factors. However, functionnal differences between Frankia root hair factor and the Nod factors have to be confirmed.Key words: Frankia, root hair deforming factor, Nod factor, actinorhizal plants.

Nod factors modulate the concentration of cytosolic free calcium differently in growing and non-growing root hairs of Medicago sativa L.

Using Ca(2+)-selective microelectrodes, the concentration of free calcium ([Ca(2+)]) in the cytosol has been measured in root hair cells of Medicago sativa L. in the presence of nodulation (Nod) factors. Growing root hairs of M. sativa displayed a steep apical [Ca(2+)] gradient, i.e. 604-967 nM in the tip compared with 95-235 nM in the basal region. When tested within the first 5 to 10 µm of the tip, addition of NodRm-IV(C16:2,S) decreased the cytosolic [Ca(2+)], whereas an increase was observed when tested behind the tip. Overall, this led to a partial dissipation of the [Ca(2+)] gradient. The Ca(2+) response was specific: it was equally well observed in the presence of NodRm-IV(Ac,C16:2,S), reduced with NodRm-IV(C16:0,S), but not with chitotetraose, the nonactive glucosamine backbone. In contrast to growing root hairs, non-growing root hairs without a tip-to-base cytosolic [Ca(2+)] gradient responded to NodRm-IV(C16:2,S) with an increase in cytosolic [Ca(2+)] at the tip as well as at the root hair base. We suggest that the response to Nod factors depends on the stage of development of the root hairs, and that changes in cytosolic [Ca(2+)] may play different roles in Nod-factor signaling: changes of cytosolic [Ca(2+)] in the apical part of the root hair may be related to root hair deformation, while the increase in [Ca(2+)] behind the tip may be essential for the amplification of the Nod signal, for its propagation and transduction to trigger downstream events.