The ethylene-inhibitor aminoethoxyvinylglycine restores normal nodulation by Rhizobium leguminosarum biovar. viciae on Vicia sativa subsp. nigra by suppressing the ‘Thick and short roots’ phenotype

Nodulation of Vicia sativa subsp. nigra L. by Rhizobium bacteria is coupled to the development of thick and short roots (Tsr). This root phenotype as well as root-hair induction (Hai) and root-hair deformation (Had) are caused by a factor(s) produced by the bacteria in response to plant flavonoids. When very low inoculum concentrations (0.5–5 bacteria·ml^-1) were used, V. sativa plants did not develop the Tsr phenotype and became nodulated earlier than plants with Tsr roots. Furthermore, the nodules of these plants were located on the primary root in contrast to nodules on Tsr roots, which were all located at sites of lateral-root emergence. The average numbers of nodules per plant were not significantly different for these two types of nodulation. Root-growth inhibition and Hai, but not Had, could be mimicked by ethephon, and inhibited by aminoethoxyvinylglycine (AVG). Addition of AVG to co-cultures of Vicia sativa and the standard inoculum concentration of 5·10⁵ bacteria·ml^-1 suppressed the development of the Tsr phenotype and restored nodulation to the pattern that was observed with very low concentrations of bacteria (0.5–5 bacteria·ml^-1). The delay in nodulation on Tsr roots appeared to be caused by the fact that nodule meristems did not develop on the primary root, but only on the emerging laterals. The relationship between Tsr, Hai, Had, and nodulation is discussed.Abbreviations AVG aminoethoxyvinylglycine - cfu colonyforming units - Had root-hair deformation - Hai root-hair induction - NB naringenin-bacteria filtrate - Tsr Thick and short roots     

Effect of nutrient medium pH on symbiotic nitrogen fixation byRhizobium leguminosarum andPisum sativum

Summary Experiments were performed to measure the pH-sensitive steps in nodulation and symbiotic fixation byPisum sativum and isolate RP-212-1 ofRhizobium leguminosarum. An aeroponic system with rigorous pH control was used to obtain numerous effective nodules. After exposure to various pH levels, the following responses were measured: (1) legume root growth and development, (2) survival and growth rate of a single effective bacterial isolate, (3) degree of nodulation, (4) rate of nitrogen fixation, (5) plant biomass, and (6) nitrogen content of plants. Both bacterial growth and root development were adequate at all pH levels from 4.4 to 6.6, but efficient nodulation and nitrogen fixation did not occur at pH 4.8 and below. The processes required for symbiosis were about 10 times as sensitive to acidity as either bacterial growth or root growth alone. Nodulation was the most acid-sensitive step.     

Nodulation in clover roots: Correlation with vacuolar pH

Abstract Nodulation patterns of three clover cultivars inoculated with three strains of Rhizobium leguminosarum bv. trifolii were established. Profiles of the frequency of nodule formation in the root-hair zone and no-root-hair zone of Trifolium subterraneum (cvs. Clare and Mount Barker) indicated a more frequent development of nodules in the no-root-hair zone. A different nodulation pattern was observed in Trifolium fragiferum cv. Palestine in which the number of nodules per centimeter did not change along the root.
In order to assess the mechanisms responsible for the different capacity of root tissues to initiate meristematic activity for nodule formation, intracellular pH of the different root zones was measured using ³¹P-NMR spectroscopy. In the two clovers with distinct zones of nodule formation, the vacuolar pH of the no-root-hair zone was 0.3 units higher than that of the root-hair zone, with a lower pH being associated with a lower nodulation frequency.     

Preincubation of Bradyrhizobium japonicum with Genistein Accelerates Nodule Development of Soybean at Suboptimal Root Zone Temperatures

In the soybean (Glycine max [L.] Merr.) N2-fixing symbiosis, suboptimal root zone temperatures (RZTs) slow nodule development, especially at temperatures below 17[deg]C. A step in the infection process that occurs within the first 24 h is particularly sensitive to suboptimal RZT. The first phase in the establishment of the soybean-Bradyrhizobium japonicum symbiosis is the exchange of recognition molecules. The most effective plant-to-bacterium signal is genistein. Binding of genistein to B. japonicum activates many of the B. japonicum nod genes. To our knowledge, the potential of sub-optimal RZT to disrupt this interorganismal signaling has not previously been investigated. Controlled environment experiments were conducted to determine whether the preincubation of B. japonicum with genistein increases soybean nodulation and N2 fixation at suboptimal RZT and whether the time between inoculation and root-hair curling is shortened by genistein application. The results of these experiments indicated that (a) genistein application increased soybean nodulation at suboptimal RZTs (17.5 and 15[deg]C) but not at the optimal RZT (25[deg]C); (b) the period between inoculation and root-hair curling was shortened by inoculation with bradyrhizobia preincubated with genistein; (c) at 17.5 and 15[deg]C RZT, the onset of N2 fixation occurred earlier in plants that received genistein-treated bradyrhizobia than in plants inoculated with untreated bradyrhizobia; (d) over the tested concentration range, genistein application at 15 to 20 [mu]M was the most effective in stimulating nodulation; and (e) between 25 and 15[deg]C, as RZT decreased, there was an increase in the nodulation-stimulating potential of genistein.     

Nonenzymatic reduction of ferric leghemoglobin

Ferric leghemoglobin isolated from soybean root nodules was reduced nonenzymatically to ferrous leghemoglobin in vitro at pH 5.2 using either 1.0 mM NADH or NADPH as the reductant. In the pH range of 5.2 to 7.0, the highest rates of reduction occurred below pH 6.5 with a maximum rate observed at pH 5.2. Rates of nonenzymatic ferric leghemoglobin reduction above pH 6.5 or at reduced-pyridine nucleotide concentrations below 0.4 mM were insignificant. Oxygen was required for the nonenzymatic reduction. Inhibition of ferric leghemoglobin reduction by superoxide dismutase and catalase indicated that superoxide and hydrogen peroxide may be intermediates in the reaction.     

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.     

Calcium transport in intact human erthrocytes

Intact human erythrocytes can be readily loaded with calcium by incubation in hypersomotic media at alkaline pH. Erythrocyte calcium content increases from 15-20 to 120-150 nmol/g hemoglobin after incubation for 2 h at 20 degree C in a 400 mosmol/kg, pH 7.8 solution containing 100 mM sodium chloride, 90 mM tetramethylammonium chloride, 1 mM potassium chloride, and 10 mM calcium chloride. Calcium uptake is a time-dependent process that is associated with an augmented efflux of potassium. The ATP content in these cells remains at more than 60% of normal and is not affected by calcium. Calcium uptake is influenced by the cationic composition of the external media. The response to potassium is diphasic. With increasing potassium concentrations, the net accumulation of calcium initially increases, becoming maximal at 1 mM potassium, then diminishes, falling below basal levels at concentrations above 3 mM potassium. Ouabain inhibits the stimulatory effect of low concentrations of potassium. The inhibitory effects of higher concentrations of potassium are ouabain insensitive and independent of the external calcium concentration. Sodium also inhibits calcium uptake but this inhibition can be modified by altering the external concentration of calcium. The effux of calcium from loaded erythrocytes is not significantly altered by changes in osmolality, medium ion composition, or ouabain. It is concluded that hypertonicity increases the net uptake of calcium by increasing the influx of calcium and that some part of the sodium potassium transport system is involved in this influx process.     

Peanut nodulation kinetics in response to low pH.

In this work, the peanut nodulation kinetics by acid-sensitive and tolerant isolates under acid stress condition was analyzed. The results demonstrated that the acid pH produced a decrease in the number of nodules formed only when peanut plants were inoculated with acid-sensitive isolates but increased steadily by the addition of 10 mM Ca2+, reaching higher values than those obtained at pH 7.0. On the contrary, the peanut nodulation by acid-tolerant isolates was not affected by this stressing condition. These data suggest that acid-tolerant isolates could be used as a potential source of strains for preparing highly effective inoculants for peanut plants growing in acid soils.     

Interactions Between High pH and Iron Supply on Nodulation and Iron Nutrition of Lupinus albus L. Genotypes Differing in Sensitivity to Iron Deficiency

Poor growth of white lupin (Lupinus albus L.) on alkaline soils may result from its sensitivity to iron deficiency and poor nodulation. This study examined interactive effects of iron supply and high pH on the growth and nodulation of three genotypes differing in their sensitivity to iron deficiency. Three genotypes (P27486, Ultra and WTD180) were grown for 17 days in buffered solutions with Fe supply of 0.2, 2 and 20 μM. Solution pH was adjusted to 5.2, 6.5 or 7.5. Plant growth, nodulation and nutrient concentrations in plants were measured. Decreasing Fe supply decreased chlorophyll concentration in young leaves by up to 92%. Increasing pH decreased chlorophyll concentration by an average of 40% at pH 6.5 and by 47% at pH 7.5. The decrease of chlorophyll was less obvious in P27485 than in Ultra or WTD180. Shoot biomass was reduced by up to 18% by Fe deficiency, with such decrease being less for P27486. Increasing pH exacerbated the effect of Fe deficiency on shoot biomass only of Ultra. Decreasing Fe supply decreased nodule number by an average of 54%, and increasing pH decreased nodule number by 80%. P27486 formed the greatest number of nodules while WTD180 the least. P27486 had high Fe uptake and low internal requirement. Irrespective of genotype, leaf chlorosis positively correlated with cluster root formation. The results suggest that a combination of Fe deficiency and high pH impaired nodulation in L. albus, and that selection of genotypes for both tolerance of iron deficiency and good nodulation at high pH is important for a successful lupin crop on alkaline soils.     

Rhizobium leguminosarum has two glucosamine syntheses, GImS and NodM, required for nodulation and development of nitrogen-fixing nodules

The Rhizobium leguminosarum nodM gene product shows strong homology to the Escherichia coli glmS gene product that catalyses the formation of glucosamine 6-P from fructose 6-P and glutamine. DNA hybridization with nodM indicated that, in addition to nodM on the symbiotic plasmid, another homologous gene was present elsewhere in the R. leguminosarum genome. A glucosamine-requiring mutant was isolated and its auxotrophy could be corrected by two different genetic loci. It could grow without glucosamine when the nodM gene on the symbiotic plasmid was induced or if the cloned nodM gene was expressed from a vector promoter. Alternatively, it could be complemented by a second fragment of R. leguminosarum DNA that carries a region homologous to E. coli glmS. Biochemical assays of glucosamine 6-P formation confirmed that the two R. leguminosarum genes nodM and glmS have interchangeable functions. No nodulation of peas or vetch was observed with a double nodM glmS mutant, and this block occurred at a very early stage since no root-hair deformation or infection threads were seen. Nodulation and root-hair deformation did occur with either the nodM or the glmS mutant, showing that the gene products of either of these genes can be involved in the formation of the lipo-oligosaccharide nodulation signal. However, the glmS mutant formed nodules that had greatly reduced nitrogen fixation. Constitutive expression of nodM restored nitrogen fixation to the glmS mutant. Therefore the reduced nitrogen fixation probably occurs because glmS is absent and nodM is not normally expressed in nodules and, in the absence of glucosamine precursors, normal bacteroid maturation is blocked.     

Host recognition in the Rhizobium-soybean symbiosis: detection of a protein factor in soybean root exudate which is involved in the nodulation process

The mechanism of host-symbiont recognition in the soybean-Rhizobium symbiosis was investigated utilizing mutants of R. japonicum defective in nodulation. Soybeans were grown in clear plastic growth pouches allowing the identification of the area on the root most susceptible to Rhizobium nodulation; the area between the root tip (RT) and smallest emergent root hair (SERH). The location of nodules in relation to this developing zone is an indication of the rate of nodule initiation. Nodules were scored as to the distance from the RT mark made at the time of inoculation. Seventy-eight per cent of the plants nodulate above the RT mark when inoculated with the wild type R. japonicum strain 3I1b110 with the average distance of the uppermost nodule being approximately 2 millimeters above the RT mark. These data indicate that the wild type strain initiates nodulation rapidly within the RT-SERH zone following inoculation. However, inoculation with the slow-to-nodulate mutant strain HS111 resulted in 100% of the plants nodulating only below the RT mark with the average distance of the uppermost nodule being approximately 56 millimeters below the RT mark. Thus, mutant strain HS111 is defective in the ability to rapidly initiate infection leading to nodulation within the RT-SERH zone. The location of the nodules suggest that stain HS111 must `adapt' to the root environment before nodulation can occur. To test this, strain HS111 was incubated in soybean root exudate prior to inoculation. In this case, 68% of the plants nodulated above the RT mark with the average distance of the uppermost nodule being approximately 1 millimeter below the RT mark. Experiments indicated that the change in nodule initiation by strain HS111 brought about by incubation in soybean root exudate was due to a phenotypic, rather than a genotypic change. The half-time of root exudate incubation for strain HS111 necessary for optimal nodulation enhancement was less than 6 hours. Heat sensitivity and trypsin sensitivity of the nodulation enhancement factor(s) in soybean root exudate indicate a protein was involved in the reversal of the delay in nodulation by mutant strain HS111.     

Role of cellulose fibrils and exopolysaccharides of Rhizobium leguminosarum in attachment to and infection of Vicia sativa root hairs

Infection and subsequent nodulation of legume host plants by the root nodule symbiote Rhizobium leguminosarum usually require attachment of the bacteria to root-hair tips. Bacterial cellulose fibrils have been shown to be involved in this attachment process but appeared not to be essential for successful nodulation. Detailed analysis of Vicia sativa root-hair infection by wild-type Rhizobium leguminosarum RBL5523 and its cellulose fibril-deficient celE mutant showed that wild-type bacteria infected elongated growing root hairs, whereas cellulose-deficient bacteria infected young emerging root hairs. Exopolysaccharide-deficient strains that retained the ability to produce cellulose fibrils could also infect elongated root hairs but infection thread colonization was defective. Cellulose-mediated agglutination of these bacteria in the root-hair curl appeared to prevent entry into the induced infection thread. Infection experiments with V sativa roots and an extracellular polysaccharide (EPS)- and cellulose-deficient double mutant showed that cellulose-mediated agglutination of the EPS-deficient bacteria in the infection thread was now abolished and that infection thread colonization was partially restored. Interestingly, in this case, infection threads were initiated in root hairs that originated from the cortical cell layers of the root and not in epidermal root hairs. Apparently, surface polysaccharides of R. leguminosarum, such as cellulose fibrils, are determining factors for infection of different developmental stages of root hairs.     

Cinnamate toxicity expression on phenylalanine ammonia-lyase activity,germination and growth of cucumber (Cucumis sativis) seedlings

Low pH (5.2) decreased nodule number and acetylene reduction. Aluminium further depressed those parameters in theRhizobium leguminosarum-Pisum sativum associations examined. In the Al-treated plants nodule formation by strains 128C53 and 128C30 was not affected by 3 or 15 and 30 or 60 μM Al, respectively, as compared with the number of nodules on plants grown at pH 5.2 in the absence of Al. However, improved nodulation rates by those strains did not enhance plant dry weight or reduced nitrogen content. No differences in nitrogenase activity were found among strains of nodulating plants grown at the same aluminium level. These results suggest that Al-ions affected specifically nitrogenase activity and that this effect was primarily responsible for the reduction in plant growth.     

Effect of orthophosphate and oxalate on the cold-induced release of calcium from sarcoplasmic reticulum preparations from rabbit skeletal muscle.

The cold-induced release of calcium from sarcoplasmic reticulum preparations from both white and red muscles of the rabbit was studied. Part of the release was due to the increase in pH of the reaction mixture with cooling. Calcium release was greatly reduced or completely prevented by the inclusion of oxalate or inorganic orthophosphate in the medium. No release occurred in 5 mM oxalate. With phosphate, the proportion of the calcium previously taken up at 23 degrees C that was released at 0 degrees C became progressively smaller as the phosphate concentration was increased. When the pH was adjusted to be the same at 0 degrees C as at 23 degrees C there was little release from white muscle preparations in 10 mM phosphate and no release when the phosphate concentration was 20 mM or more. With red muscle preparations calcium was released at higher phosphate concentrations, 8% of the amount previously taken up still being released at 50 mM phosphate and a smaller amount at 100 mM phosphate. The effects of oxalate and phosphate can be explained in terms of the reduction in free calcium concentration inside the vesicles by calcium precipitants, and a difference in the temperature coefficients of calcium inflow and outflow.     

Effects of phosphorus and nitrogen on nodulation are seen already at the stage of early cortical cell divisions in Alnus incana

BACKGROUND AND AIMS: The present work aimed to study early stages of nodulation in a chronological sequence and to study phosphorus and nitrogen effects on early stages of nodulation in Alnus incana infected by Frankia. A method was developed to quantify early nodulation stages in intact root systems in the root hair-infected actinorhizal plant A. incana. Plant tissue responses were followed every 2 d until 14 d after inoculation. Cortical cell divisions were already seen 2 d after inoculation with Frankia. Cortical cell division areas, prenodules, nodule primordia and emerging nodules were quantified as host responses to infection. METHODS: Seedlings were grown in pouches and received different levels of phosphorus and nitrogen. Four levels of phosphorus (from 0.03 to 1 mM P) and two levels of nitrogen (0.71 and 6.45 mM N) were used to study P and N effects on these early stages of nodule development. KEY RESULTS: P at a medium concentration (0.1 mM) stimulated cell divisions in the cortex and a number of prenodules, nodule primordia and emerging nodules as compared with higher or lower P levels. A high N level inhibited early cell divisions in the cortex, and this was particularly evident when the length of cell division areas and presence of the nodulation stages were related to root length. CONCLUSIONS: Extended cortical cell division areas were found that have not been previously shown in A. incana. The results show that effects of P and N are already expressed at the stage when the first cortical cell divisions are induced by Frankia.     

Phosphorus-induced micronutrient disorders in hybrid poplar

The effect of calcium on the nodulation of lucerne was studied using EGTA, a specific calcium-chelator. First, the effects of the chelator were tested on hydroponically grown plants at pH 7.0. Optimal numbers of nodules were obtained in nutrient solution containing 0.2 mM CaCl₂. When 0.4 mM EGTA was given additionally, nodulation was completely inhibited. Nodulation was restored specifically with CaCl₂, but not with MgCl₂. For studies in an acid soil (pH-H₂O 5.2), lucerne seedlings were grown in rhizotrons. 67% of the seedlings became nodulated when the soil around the seed was neutralized locally with 1.0 μmol of K₂CO₃ in drops of 12 μL volume. When native calcium was removed with 2 μmol of EGTA, nodulation was reduced to 12%. However, addition of EGTA to soil resulted in a drop of pH from 6.1 to 5.2. A phosphate buffer could also not keep soil-pH sufficiently stable. Such pH-decreases could be avoided by placing agar blocks containing 6 μmol of EGTA for three hours on freshly developed roots. This treatment reduced nodulation from 87% to 32%, with soil-pH lowering only from 6.2 to 6.0. Nodulation could be restored by adding 2 μmol of CaCl₂. The depletion of soil-calcium could depress nodule formation only during the first day after inoculation.     

Root-hair infection and nodulation of four grain legumes as affected by the form and the application time of nitrogen fertilizer

The effects of application of combined nitrogen fertilizer (ammonium nitrate or urea) on root-hair infection and nodulation of four grain legumes were studied. Young roots of each legume were inoculated with their compatible rhizobia. The application of the two forms of combined N either at the early stages of plant growth and/or at the time of nodule formation depressed root-hair curling, infection and nodulation. Infection of hairs on the primary roots was more sensitive to the N fertilizer than hair infection of secondary roots in bothVicia faba andPisum sativum. The nodule number and total fresh mass of the four legumes were drastically affected by fertilizer application. The combined N added both at early and at later stages significantly reduced the nodulation ofV. faba, Phaseolus vulgaris andVigna sinensis. The inhibitory effect of urea on nodulation ofP. sativum was only observed when the fertilizer was applied at the late stages of plant growth. It is concluded that, although the nodulation of the four legumes was suppressed by combined N, the initial events ofRhizobium-legume symbiosis (infection of roots and nodule initiation) are more sensitive to combined N than the stages after nodule formation.     

The effect of short term withdrawal of NaCl stress on nodulation of white clover

The number of nodules formed by white clover (Trifolium repens L.) released from NaCl stress for 3 days (137 mol m^-3) at different periods was examined. The NaCl stress-free periods were, 0 to 3 days prior to rhizobial inoculation, 0 to 3, 3 to 6, and 6 to 9 days after rhizobial inoculation. Plants not subjected to NaCl stress at 0 to 3 days after inoculation had 28.7 nodules per plant (74% of control), while plants continuously stressed had 5.2 nodules (13% of control). A NaCl stress-free period immediately after inoculation was the best among the stressed treatments, indicating that the early stage of nodulation was more sensitive than the later stages. Microscopic observation showed that imposing NaCl stress during the first 3 days after inoculation suppressed root hair curling to 9.1% of control, while the numbers of rhizobia attached to roots counted by dilution plates were not affected. Thus, there were no significant effects of NaCl stress on rhizobia. The sensitivity of the early stage of infection to NaCl stress was attributed to the inhibition of root hair curling.     

Nodulation and growth ofPhaseolus vulgaris in solution culture

Summary Conditions and techniques for achieving good nodulation ofPhaseolus vulgaris L. in continuously aerated solution were developed from greenhouse experiments.If nodules had been established, their growth and activity and the growth of the plant were at least as good in solution culture as in gravel culture. Nodule formation was observed within 10 days of inoculation in small volumes of solution culture (1 liter). In large volumes (19 liters), similarly prompt nodulation occurred only if the plants were inoculated before or immediately after the seedlings were transferred to the solution from gravel or vermiculite; and the nodules were restricted to the roots that had been present at the time of transfer. Delayed inoculation, 2 days after transfer to large volume solutions, led to sparse nodulation observed only after 3 weeks. Delay or inhibition of nodulation in large volumes of solution could not be explained by failute of bacteria to colonize roots or by sparsity of root hairs.Nodule initiation in solution culture was severely inhibited at pH below 5.4. An additional problem in growing N₂-dependent bean in solution culture was the buildup of Cl^– to toxic levels in the plant in nitrate-free media, even at solution concentrations as low as 0.4 mM Cl^–. Daily addition of 0.5 to 1.0 mg N per plant delayed nodule growth and activity slightly, but increased plant growth and alleviated the severe N-deficiency that otherwise developed before the onset of N₂-fixation.     

Propyl gallate,a free radical scavenger,counteracts the benefits of exogenously applied salicylic acid and aggravates the deleterious effects of the southern bean mosaic virus in Rhizobium-nodulated Phaseolus vulgaris plants

Infection of Rhizobium-nodulated Phaseolus vulgaris by the southern bean mosaic virus (SBMV) markedly decreased the growth and nodulation of plants. Exogenous applications of salicylic acid (SA) at concentrations ≥10 μM further decreased growth and nodulation of virus-infected (V) plants. Only SA concentration of 5 μM in the solution improved the growth, nodulation, chlorophyll concentration and the catabolism of ureide in leaves of V plants. The spray of leaves with 2 mM propyl gallate (+Pg) decreased growth, nodulation as well as the chlorophyll and leaf ureide concentrations in V plants, regardless of the concentration of SA at which plants were grown. Ultrastructural damages in leaf cells caused by SBMV were also enhanced in V+Pg plants. The massive proliferation of virus particles and the presence of virus crystalline arrays within symbiosomes of nodules in V+Pg plants were attributed to proliferation of branched plasmodesmata in leaf vascular-parenchyma cell walls that facilitated virus movement. Virus particles were never observed in leaf and nodule tissues of V plants not sprayed with Pg. Exogenous applications of SA hindered while Pg increased the symbiotic performance of H plants, pointing out the complexity to be addressed in breeding for virus resistance in Rhizobium-nodulated beans.