Comparative differential RNA display analysis of arbuscular mycorrhiza in Pisum sativum wild type and a mutant defective in late stage development

In order to analyse gene expression associated with the late stages of arbuscular mycorrhizal development between Pisum sativum and Glomus mosseae, comparative differential RNA display was carried out using wild-type P. sativum and a mutant, RisNod24, where the fungal partner is not able to form functional arbuscules. Comparison of RNA accumulation patterns between controls, G. mosseae-colonized mutant and wild-type roots resulted in the identification of four differentially occurring cDNA fragments. One of the corresponding genes was from the fungus and three of plant origin. One plant gene, Psam4 (P. sativum arbuscular mycorrhiza-regulated), was analysed in more detail. Sequencing of a cDNA clone showed that Psam4 encodes a proline-rich protein. Northern blot analysis and quantitative RT-PCR revealed a higher basal level of Psam4 RNA accumulation in the mutant compared to the wild type. In both pea genotypes, RNA accumulation was reduced after inoculation with mycorrhiza- or nodule-forming symbiotic microorganisms, but enhanced after infection with a root pathogenic fungus.     

Possible Involvement of Hydrogen Peroxide and Salicylic Acid in the Legume-Rhizobium Symbiosis

H₂O₂ content was studied in the roots and epicotyls of pea (Pisum sativum L.) with normal (cultivar Marat) and disturbed (non-nodulating mutant K14a and hypernodulating mutant Nod3) regulation of root nodulation after inoculation with active industrial strain of Rhizobium leguminosarum bv. viceae 250a/CIAM 1026. Pea biotypes differed by H₂O₂ content in roots and epicotyls. Exogenous salicylic acid (SA) (0.2 mM) affected H₂O₂ and SA levels in roots in an inoculation-dependent manner. The involvement of hydrogen peroxide and SA as signaling molecules as well as of antibacterial agents in the pea-rhizobium interaction at the initial stages of symbiosis is proposed.__________Translated from Izvestiya Akademii Nauk, Seriya Biologicheskaya, No. 3, 2005, pp. 300–305.Original Russian Text Copyright © 2005 by Glyan’ko, Makarova, Vasil’eva, Mironova.     

Secondary metabolite profiling of the model legume <Emphasis Type="Italic">Lotus japonicus</Emphasis> during its symbiotic interaction with <Emphasis Type="Italic">Mesorhizobium loti</Emphasis>

Plant secondary metabolites, particularly flavonoids, are key components in the early stages of nitrogen-fixing symbiosis. Despite their importance, the endogenous secondary metabolites involved in symbiosis have not yet been identified in the model legume Lotus japonicus. We therefore determined changes in the secondary metabolic profile of Lotus japonicus roots in response to its symbiont. Analysis of the root secondary metabolite profiles 1 week after inoculation with Mesorhizobium loti revealed quantitative changes in the level of 14 phenolic peaks when compared with non-inoculated control plants. These changes affected compounds from most phenolic classes, possibly resulting from interconversion between classes since the total phenolic level remained constant. In addition, the use of 2 M. loti strains differing only in their capacity to synthesise Nod factor revealed that, although Nod factor signalling induced accumulation of a specific subset of 4 phenolic peaks, most changes were induced in response to both rhizobial strains.     

Efficiency of respiration and energy requirements of N assimilation in roots of Pisum sativum

The function of alternative path respiration in roots was investigated in pea plants (Pisum sativum L. cv. Rondo). Plants were grown in symbiosis with Rhizobium leguminosarum (strain PF2), completely dependent on N₂ fixation, or non-nodulated, receiving nitrate or ammonium at the same rate as N₂ was fixed in symbiosis. Under these conditions, relative growth rates of plants grown with N₂, NO^-₃ or NH⁺₄ were the same. This facilitated interpretation of the effect of the N source on the efficiency of root respiration, as determined by the relative activity of the non-phosphorylating alternative path. The ‘wasteful’ oxidation of carbohydrate via this pathway was defined as the glucose equivalent of the difference between the amounts of ATP (mol O₂)^-1 produced in cytochrome and alternative path respiration. ‘Wasteful’ carbohydrate oxidation maximally amounted to 4% (N₂), 15% (NO^-₃) and 25% (NH⁺₄) of the daily carbohydrate oxidation in the roots. It is concluded that the ‘wasteful’ oxidation of carbohydrate via the alternative path is of minor importance for the adaptation of root respiratory metabolism to different energy requirements of N assimilation. The total carbohydrate import by roots fixing N₂ was ca 60 and 30% higher than the import by roots assimilating NO^-₃ or NH⁺₄, respectively. Two factors are shown to account for these differences: the high carbohydrate cost of N₂ fixation, and the small contribution (30%) of the roots to NO^-₃ reduction by the plant. The high carbohydrate requirements of roots fixing N₂ were met by higher rates of photosynthesis as compared with plants utilizing NO^-₃ or NH⁺₄.     

A Medicago truncatula mutant hyper-responsive to mycorrhiza and defective for nodulation

One key strategy for the identification of plant genes required for mycorrhizal development is the use of plant mutants affected in mycorrhizal colonisation. In this paper, we report a new Medicago truncatula mutant defective for nodulation but hypermycorrhizal for symbiosis development and response. This mutant, called B9, presents a poor shoot and, especially, root development with short laterals. Inoculation with Glomus intraradices results in significantly higher root colonisation of the mutant than the wild-type genotype A17 (+20% for total root length, +16% for arbuscule frequency in the colonised part of the root, +39% for arbuscule frequency in the total root system). Mycorrhizal effects on shoot and root biomass of B9 plants are about twofold greater than in the wild-type genotype. The B9 mutant of M. truncatula is characterised by considerably higher root concentrations of the phytoestrogen coumestrol and by the novel synthesis of the coumestrol conjugate malonyl glycoside, absent from roots of wild-type plants. In conclusion, this is the first time that a hypermycorrhizal plant mutant affected negatively for nodulation (Myc⁺⁺, Nod ^−/+ phenotype) is reported. This mutant represents a new tool for the study of plant genes differentially regulating mycorrhiza and nodulation symbioses, in particular, those related to autoregulation mechanisms.     

Sucrose synthase levels do not limit or regulate carbon transfer in the arbuscular mycorrhizal symbiosis

Abstract

Sucrose synthase (SuSy) is the main sucrose breakdown enzyme in plant sink tissues, including nodules, and is a possible candidate for the diversion of plant carbon to arbuscular mycorrhizal (AM) fungi in roots. We tested the involvement of SuSy in AM symbiosis of Glomus intraradices and Pisum sativum (pea). We observed that peas deficient in the predominant root isoform of SuSy were colonized successfully by AM fungi similar to wild-type roots. SuSy protein levels did not increase in roots as AM symbiosis developed, although SuSy protein levels did increase in nodules as the rhizobium symbiosis developed. Our results lead us to conclude that, unlike nodule symbiosis, SuSy protein does not limit or regulate carbon transfer in the AM symbiosis.     

Strigolactones promote nodulation in pea

Strigolactones are recently defined plant hormones with roles in mycorrhizal symbiosis and shoot and root architecture. Their potential role in controlling nodulation, the related symbiosis between legumes and Rhizobium bacteria, was explored using the strigolactone-deficient rms1 mutant in pea (Pisum sativum L.). This work indicates that endogenous strigolactones are positive regulators of nodulation in pea, required for optimal nodule number but not for nodule formation per se. rms1 mutant root exudates and root tissue are almost completely deficient in strigolactones, and rms1 mutant plants have approximately 40% fewer nodules than wild-type plants. Treatment with the synthetic strigolactone GR24 elevated nodule number in wild-type pea plants and also elevated nodule number in rms1 mutant plants to a level similar to that seen in untreated wild-type plants. Grafting studies revealed that nodule number and strigolactone levels in root tissue of rms1 roots were unaffected by grafting to wild-type scions indicating that strigolactones in the root, but not shoot-derived factors, regulate nodule number and provide the first direct evidence that the shoot does not make a major contribution to root strigolactone levels.     

Characterization of a binding site for chemically synthesized lipo-oligosaccharidic NodRm factors in particulate fractions prepared from roots

This paper describes the characteristics of a binding site for the major, lipo-oligosaccharide Nod factor of Rhizobium meliloti in roots of the symbiotic host plant, Medicago truncatula. Chemically synthesized NodRm-IV(Ac, S, C16:2) was labelled by tritiation to a specific activity of 56 Ci mmol^?1 and this ligand was shown to be biologically active in the root hair deformation assay at 10^?11 M. Binding of the ligand to a particulate fraction from roots of M. truncatula was found to be saturable and reversible with an affinity (K_d) of 86 nM and the binding characteristics were consistent with a single class of binding sites. Competition with modified Nod factors showed that the binding was independent of both the O-acetyl and the sulphyl group and did not depend on the unsaturation of the fatty acid. However, both moieties of the lipo-oligosaccharide are required for high-affinity binding since tetra-N-acetyl-chitotetraose and palmitate were found to be poor competitors of ligand binding. A binding site with analogous characteristics was also found in a similarly prepared particulate fraction of tomato roots. This binding site for Nod factors, termed NFBS1, which is present in both a leguminous and a non-leguminous plant, may have a more general role than symbiosis.     

Systemic Resistance in Tomato Induced by Biocontrol Bacteria Against the Root-Knot Nematode, Meloidogyne javanica is Independent of Salicylic Acid Production

Salicylic acid (SA)‐mediated induction of systemic resistance by Pseudomonas aeruginosa strain 7NSK2 and P. fluorescens strain CHA0 against soil‐borne fungi and viruses have been reported. The role of SA biosynthesis in the enhancement of defence mechanism against plant‐parasitic nematodes by these bacterial strains in tomato is not known. To better understand the importance of SA in rhizobacteria‐mediated suppression of root‐knot nematodes, biocontrol potential of SA‐negative or SA‐overproducing mutants against Meloidogyne javanica was evaluated with their respective wild type counter parts. Culture supernatant of 7NSK2, CHA0 and their respective mutants caused significant mortality of M. javanica juveniles in vitro. SA deletion in 7NSK2 and SA overproduction in CHA0 did not influence bacterial efficacy to cause nematode deaths. Similarly, culture supernatants resulting from King's B liquid medium amended with FeCl₃ did not influence nematicidal activity of the bacterial strains. Strain CHA0 induced juvenile deaths more than 7NSK2 did. In pot experiments, the bacterial strains applied in unsterilized sandy loam soil markedly reduced final nematode population densities in roots and subsequent root‐knot infection in tomato seedlings. SA‐negative or overproducing derivatives prevented tomato roots in kinetics similar to those with their respective wild types. When soil iron concentration was lowered by the addition of ethylenediamine di(o‐hydroxyphenylacetic acid), nematode biocontrol by the bacterial strains (both wild type and mutants) remained unaltered. To understand the mechanism involved in rhizobacteria‐mediated suppression of root‐knot nematode in tomato, bacterial performance was assessed in a split root trial in which one‐half of the root system was treated with bacterium while the other inoculated with nematode. Compared with the controls, application of the bacterial cell suspension to one‐half of the root system lowered the populations of root‐knot nematode in non‐bacterized nematode‐treated sections indicating enhanced defence in the non‐bacterized half. With respect to nematode infection, mutants induced systemic resistance to a similar extent as that caused by the wild types in both wild type tomato and NahG tomato plants. It is concluded that fluorescent pseudomonads induce systemic resistance against root‐knot nematode via a signal transduction pathway, which is independent of SA accumulation in roots.     

Structural modifications in Rhizobium meliloti Nod factors influence their stability against hydrolysis by root chitinases

Acylated chitooligosaccharide signals (Nod factors) trigger the development of root nodules on leguminous plants and play an important role in determining host specificity in the Rhizobium-plant symbiosis. Here, the ability of plant chitinases to hydrolyze different Nod factors and the potential significance of the structural modifications of Nod factors in stabilizing them against enzymatic inactivation were investigated. Incubation of the sulfated Nod factors of Rhizobium meliloti, NodRm-IV(S) and NodRm-V(S), as well as their desulfated derivatives NodRm-IV and NodRm-V, with purified chitinases from the roots of the host plant Medicago and the nonhost plant Vicia resulted in the release of the acylated lipotrisaccharide NodRm-III from NodRm-V, NodRm-IV and NodRm-V(S), whereas NodRm-IV(S) was completely resistant to digestion by both chitinases. Kinetic analysis showed that the structural parameters determining host specificity, the length of the oligosaccharide chain, the acylation at the nonreducing end and the sulfatation at the reducing end of the lipooligosaccharide, influence the stability of the molecule against degradation by chitinases. When the Nod factors were incubated in the presence of intact roots of Medicago, as well as of Vicia, the acylated lipotrisaccharide was similarly released in vivo from all Nod factors except NodRm-IV(S). In addition, a dimer-forming activity was observed in intact roots which also cleaved NodRm-IV(S). This activity was much greater in Medicago than in Vicia and increased upon incubation. The initial overall degradation rate of the Nod factors on Medicago was inversely correlated with their biological activities on Medicago roots. These results open the possibility that the activity of Nod factors on Medicago may partly be determined by the action of chitinases.     

Charcoal and shrubs modify soil processes in ponderosa pine forests of western Montana

In split-root systems of alfalfa (Medicago sativa L.), already existing nodules or arbuscular mycorrhizal roots suppress further establishment of symbiosis in other root parts, a phenomenon named autoregulation. Roots treated with rhizobial nodulation signals (Nod factors) induce a similar systemic suppression of symbiosis.In order to test the hypothesis that flavonoids play a role in this systemic suppression, split-root systems of alfalfa plants were inoculated on one side of the split-root system with Sinorhizobium meliloti or Glomus mosseae or were treated with Nod factor. HPLC-analysis of alfalfa root extracts from both sides of the split-root system revealed a persistent local and systemic accumulation pattern of some flavonoids associated with the different treatments. The two flavonoids, formononetin and ononin, could be identified to be similarily altered after rhizobial or mycorrhizal inoculation or when treated with Nod factor.Exogenous application of formononetin and ononin partially restored nodulation and mycorrhization pointing towards the involvement of these two secondary compounds in the autoregulation of both symbioses.     

Uptake and translocation of phosphate by pho2 mutant and wild-type seedlings of Arabidopsis thaliana

The pho2 mutant of Arabidopsis thaliana (L.) Heynh. accumulates excessive Pi (inorganic phosphate) concentrations in shoots compared to wild-type plants (E. Delhaize and P. Randall, 1995, Plant Physiol. 107: 207–213). In this study, a series of experiments was conducted to compare the uptake and translocation of Pi by pho2 with that of wild-type plants. The pho2 mutants had about a twofold greater Pi uptake rate than wild-type plants under P-sufficient conditions and a greater proportion of the Pi taken up accumulated in shoots of pho2. When shoots were removed, the uptake rate by roots was found to be similar for both genotypes, suggesting that the greater Pi uptake by the intact pho2 mutant is due to a greater shoot sink for Pi. Although pho2 mutants could recycle ³²Pi from shoots to roots through phloem the proportion of ³²Pi translocated to roots was less than half of that found in wild-type plants. When transferred from P-sufficient to P-deficient solutions, Pi concentrations in pho2 roots had a similar depletion rate to wild-type roots despite pho2 shoots having a fourfold greater Pi concentration than wild-type shoots throughout the experiment. We suggest that the pho2 phenotype could result from a partial defect in Pi transport in the phloem between shoots and roots or from an inability of shoot cells to regulate internal Pi concentrations. Received: 20 August 1997 / Accepted: 4 October 1997     

Plant Responses to Drought Stress and Exogenous ABA Application are Modulated Differently by Mycorrhization in Tomato and an ABA-deficient Mutant (<Emphasis Type="Italic">Sitiens</Emphasis>)

The aims of the present study are to find out whether the effects of arbuscular mycorrhizal (AM) symbiosis on plant resistance to water deficit are mediated by the endogenous abscisic acid (ABA) content of the host plant and whether the exogenous ABA application modifies such effects. The ABA-deficient tomato mutant sitiens and its near-isogenic wild-type parental line were used. Plant development, physiology, and expression of plant genes expected to be modulated by AM symbiosis, drought, and ABA were studied. Results showed that only wild-type tomato plants responded positively to mycorrhizal inoculation, while AM symbiosis was not observed to have any effect on plant development in sitiens plants grown under well-watered conditions. The application of ABA to sitiens plants enhanced plant growth both under well-watered and drought stress conditions. In respect to sitiens plants subjected to drought stress, the addition of ABA had a cumulative effect in relation to that of inoculation with G. intraradices. Most of the genes analyzed in this study showed different regulation patterns in wild-type and sitiens plants, suggesting that their gene expression is modulated by the plant ABA phenotype. In the same way, the colonization of roots with the AM fungus G. intraradices differently regulated the expression of these genes in wild-type and in sitiens plants, which could explain the distinctive effect of the symbiosis on each plant ABA phenotype. This also suggests that the effects of the AM symbiosis on plant responses and resistance to water deficit are mediated by the plant ABA phenotype.     

Methyl jasmonate and salicylic acid elicitation induces ginsenosides accumulation, enzymatic and non-enzymatic antioxidant in suspension culture Panax ginseng roots in bioreactors

The effects of methyl jasmonate (MJ) and salicylic acid (SA) on changes of the activities of major antioxidant enzymes, superoxide anion accumulation (O₂ ⁻), ascorbate, total glutathione (TG), malondialdehyde (MDA) content and ginsenoside accumulation were investigated in ginseng roots (Panax ginseng L.) in 4 l (working volume) air lift bioreactors. Single treatment of 200 μM MJ and SA to P. ginseng roots enhanced ginsenoside accumulation compared to the control and harvested 3, 5, 7 and 9 days after treatment. MJ and SA treatment induced an oxidative stress in P. ginseng roots, as shown by an increase in lipid peroxidation due to rise in O₂ ⁻ accumulation. Activity of superoxide dismutase (SOD) was inhibited in MJ-treated roots, while the activities of monodehydroascorbate reductase (MDHAR), dehydroascorbate reductase (DHAR), SOD, guaiacol peroxidase (G-POD), glutathione peroxidase (GPx) and glutathione reductase (GR) were induced in SA-treated roots. A strong decrease in the activity of catalase (CAT) was obtained in both MJ- and SA-treated roots. Activities of ascorbate peroxidase (APX) and glutathione S transferase (GST) were higher in MJ than SA while the contents of reduced ascorbate (ASC), redox state (ASC/(ASC+DHA)) and TG were higher in SA- than MJ-treated roots while oxidized ascorbate (DHA) decreased in both cases. The result of these analyses suggests that roots are better protected against the O₂ ⁻ stress, thus mitigating MJ and SA stress. The information obtained in this work is useful for efficient large-scale production of ginsenoside by plant-root cultures.     

Effects of boron and calcium nutrition on the establishment of the Rhizobium leguminosarum–pea (Pisum sativum) symbiosis and nodule development under salt stress

The effects of modifying boron (B) and calcium (Ca²⁺) concentrations on the establishment and development of rhizobial symbiosis in Pisum sativum plants grown under salt stress were investigated. Salinity almost completely inhibited the nodulation of pea plants by Rhizobium leguminosarum bv. viciae 3841. This effect was prevented by addition of Ca²⁺ during plant growth. The capacity of root exudates derived from salt‐treated plants to induce Rhizobium nod genes was not significantly decreased. However, bacterial adsorption to roots was highly inhibited in plants grown with 75 mM NaCl. Moreover, R. leguminosarum 3841 did not grow in minimal media containing such salt concentration. High Ca²⁺ levels enhanced both rhizobial growth and adsorption to roots, and increased nodule number in the presence of high salt. Nevertheless, the nodules developed were not functional unless the B concentration was also increased. Because B has a strong effect on infection and cell invasion, these processes were investigated by fluorescence microscopy in pea nodules harbouring a R. leguminosarum strain that expresses green fluorescent protein. Salt‐stressed plants had empty nodules and only those treated with high B and high Ca²⁺ developed infection threads and exhibited enhanced cell and tissue invasion by Rhizobium. Overall, the results indicate that Ca²⁺ promotes nodulation and B nodule development leading to an increase of salt tolerance of nodulated legumes.     

根瘤菌NOD因子的感知与信号传导

根瘤菌是一类引起豆科植物结瘤固氮的土壤细菌。根瘤中的类菌体固定空气中的氮气为宿主植物提供充足的氮源。共生体系的建立始于细菌与宿主植物间复杂的信号交换过程。植物产生类黄酮诱导相应的根瘤菌合成分泌结瘤因子 ,后者进而诱导宿主植物根系形态变化以及早期根瘤素基因表达。以下将就宿主植物结瘤因子的特异识别和早期信号传导进行讨论。     

Effetti Morfologici,Anatomici Ed Ultrastrutturali Indotti Dai Ritardanti Di Crescita Su Plantule Di Pisum Sativum L. Var. « Gloria Di Quimper » Cultivate in Soluzione Nutritizia

Abstract

The effect of the growth retardants on the structure of Pea seedlings coltured in nutritive solution. – The addition of CCC (2-Chloro-ethyltrimethyl ammonium chloride) and AMO 1618 (4-Hydroxyl-5-isopropyl-2 methyl-phenyl-trimethylammonium chloride. 1-piperidine carboxylate) to Pea seedlings (Pisum sativum L. var. Gloria di Quimper) promotes the usual modifications induced by growth retardants on higher plants. CCC appears less effective than AMO 1618; CCC inhibits growth only at 10²-M. concentration, on the contrary 5×10-⁵M. AMO 1618 inhibits strongly the growth of the seedlings both in the light and in darkness. CCC and AMO 1618 operate similarly as far as the inhibition of expansion growth, the increase of the stem diameter, and the decrease of the apical dominance are concerned. 10-²M. CCC stimulates both the growth of roots and the secondary roots formation, on the contrary 2,5×10-⁴M. AMO 1618 inhibits strongly the growth of the roots. AMO 1618 affects more strongly than CCC the expantion growth of the leaves. Leaves of the AMO 1618 treated plants are greener than the control plants. Plants treated with CCC and AMO 1618 are smaller because these chemicals inhibit the expantion growth of the cells. The increase of the stem diameter induced by CCC and AMO 1618 is due to the stimulation of the mitotic activity of the cambium. AMO and CCC induce a decrease of the size of the vessels and the sieve tubes. In the sieve tubes of the treated plants and slime plugs appear near to the sieve plates many slime bodies. AMO and CCC did not affect the mitotic activity of the apical meristems; in fact the plants grown in the presence of the growth retardants, show a normal primary body. AMO and CCC delay the lignification process. Chloroplasts of this Pisum sativum variety show prolamellary bodies associated to a good lamellar system. Starch granules are always present. Starch was never found in the chloroplasts of the treated plants. The general picture of the effects induced by growth retardants in Pea seedlings show so many modifications that it is very difficult to believe, like some Authors suggest, that all the effects produced by growth retardants are due to the inhibition of gibberellin biosynthesis.     

Arbuscular mycorrhiza improve growth,nitrogen uptake,and nitrogen use efficiency in wheat grown under elevated CO<Subscript>2</Subscript>

Effects of the arbuscular mycorrhizal (AM) fungus Rhizophagus irregularis on plant growth, carbon (C) and nitrogen (N) accumulation, and partitioning was investigated in Triticum aestivum L. plants grown under elevated CO₂ in a pot experiment. Wheat plants inoculated or not inoculated with the AM fungus were grown in two glasshouse cells with different CO₂ concentrations (400 and 700 ppm) for 10 weeks. A ¹⁵N isotope labeling technique was used to trace plant N uptake. Results showed that elevated CO₂ increased AM fungal colonization. Under CO₂ elevation, AM plants had higher C concentration and higher plant biomass than the non-AM plants. CO₂ elevation did not affect C and N partitioning in plant organs, while AM symbiosis increased C and N allocation into the roots. In addition, plant C and N accumulation, ¹⁵N recovery rate, and N use efficiency (NUE) were significantly higher in AM plants than in non-AM controls under CO₂ enrichment. It is concluded that AM symbiosis favors C and N partitioning in roots, increases C accumulation and N uptake, and leads to greater NUE in wheat plants grown at elevated CO₂.