Differences in Endogenous Levels of Gibberellin-Like Substances in Nodules of Phaseolus lunatus L. Plants Inoculated with Two Rhizobium Strains

Lima bean plants (Phaseolus lunatus L.) inoculated with Rhizobium sp. strain 127E14, which lacks constitutive nitrate reductase activity, were significantly taller after 4 weeks of age than plants inoculated with strain 127E15, which contains constitutive nitrate reductase activity. Plants inoculated with either strain responded to application of 5 micrograms gibberellic acid per plant with rapid internode elongation; plants inoculated with strain 127E15 became less responsive to gibberellic acid from 3 to 5 weeks of age, while plants inoculated with strain 127E14 did not. The height of plants inoculated with strain 127E14 was reduced by 20% with application of gibberellin biosynthesis inhibitors to the roots, while height of plants inoculated with strain 127E15 was unaffected.     

Enhanced expression of Rhizobium etli cbb 3 oxidase improves drought tolerance of common bean symbiotic nitrogen fixation

To investigate the involvement of Rhizobium etli cbb (3) oxidase in the response of Phaseolus vulgaris to drought, common bean plants were inoculated with the R. etli strain, CFNX713, overexpressing this oxidase in bacteroids (cbb (3) (+)) and subjected to drought conditions. The negative effect of drought on plant and nodule dryweight, nitrogen content, and nodule functionality was more pronounced in plants inoculated with the wild-type (WT) strain than in those inoculated with the cbb (3) (+) strain. Regardless of the plant treatment, bacteroids produced by the cbb (3) (+) strain showed higher respiratory capacity than those produced by the WT strain. Inoculation of plants with the cbb (3) (+) strain alleviated the negative effect of a moderate drought on the respiratory capacity of bacteroids and the energy charge of the nodules. Expression of the FixP and FixO components of the cbb (3) oxidase was higher in bacteroids of the cbb (3) (+) strain than in those of the WT strain under all experimental conditions. The decline in sucrose synthase activity and the decrease in dicarboxylic acids provoked by moderate drought stress were more pronounced in nodules from plants inoculated with the WT strain than in those inoculated with the cbb (3) (+) strain. Taken together, these results suggest that inoculation of plants with a R. etli strain having enhanced expression of cbb (3) oxidase in bacteroids reduces the sensitivity of P. vulgaris-R. etli symbiosis to drought and can modulate carbon metabolism in nodules.     

Alterations in plant growth and in root hormone levels of lodgepole pines inoculated with rhizobacteria.

The presence of other soil microorganisms might influence the ability of rhizobacterial inoculants to promote plant growth either by reducing contact between the inoculant and the plant root or by interfering with the mechanism(s) involved in rhizobacterially mediated growth promotion. We conducted the following experiments to determine whether reductions in the extent of growth promotion of lodgepole pine mediated by Paenibacillus polymyxa occur in the presence of a forest soil isolate (Pseudomonas fluorescens M20) and whether changes in plant growth promotion mediated by P. polymyxa (i) are related to changes in P. polymyxa density in the rhizosphere or (ii) result from alterations in root hormone levels. The extent of plant growth, P. polymyxa rhizosphere density, and root hormone concentrations were determined for lodgepole pine treated with (i) a single growth-promoting rhizobacterial strain (P. polymyxa L6 or Pw-2) or (ii) a combination of bacteria: strain L6 + strain M20 or strain Pw-2 + strain M20. There was no difference in the growth of pines inoculated with strain L6 and those inoculated with strain L6 + strain M20. However, seedlings inoculated with strain Pw-2 had more lateral roots and greater root mass at 12 weeks after inoculation than plants inoculated with strain Pw-2 + strain M20. The extent of growth promotion mediated by P. polymyxa L6 and Pw-2 in each treatment was not correlated to the average population density of each strain in the rhizosphere. Bacterial species-specific effects were observed in root hormone levels: indole-3-acetic acid concentration was elevated in roots inoculated with P. polymyxa L6 or Pw-2, while dihydrozeatin riboside concentration was elevated in roots inoculated with P. fluorescens M20.     

Development and growth effects in the Sorghum–Azospirillum association

Sorghum plants were inoculated with a pigmented strain of Azospirillum brasilense (Cd) or were not inoculated and received an N-amended nutrient solution (1.0 mmol/l NH₄NO₃). A third set of plants were non-inoculated and not fertilized with N (control). Plants were grown in a steam-sterilized, low-fertility soil and harvested after growing for 2, 4, 6, 8 and 10 weeks. Dry weights for Azospirillum -inoculated plants were significantly greater than the N-fertilized sorghum at weeks 2 and 4, but A. brasilense -colonized plants weighed significantly less than the N-fertilized sorghum at weeks 8 and 10. Shoot and root N concentrations increased for N-amended plants but remained fairly steady for sorghum inoculated with strain Cd indicating enhanced N-use efficiency in plants colonized with the endophyte. In general, the concentration of Fe, Mn, Zn and Cu in Azospirillum -colonized plants was relatively less than that in N-amended sorghum early in ontogeny when the growth rate of the inoculated plants was greatest. The number of inoculated Cd cells per plant was correlated with percentage increase in dry weight ( r = 0.92*) or total N content ( r = 0.93*) relative to the N-fertilized plants. Growth enhancement relative to N-fertilized sorghum was not observed when the number of Azospirillum cells per gram of root dropped below 1.0 x 10⁵ (or 3.0 x 10⁶ cells/plant). Therefore, the persistence of Azospirillum in the endorhizosphere of sorghum had a direct impact on host growth, physiology and nutrition.     

Physiological Characteristics of Cowpea Rhizobia: Evaluation of Symbiotic Efficiency in Vigna unguiculata

One fast-growing and three slow-growing strains of Rhizobium (isolated from cowpeas) were evaluated for symbiotic performance on Vigna unguiculata (L.) Walp. cultivar California no. 5 blackeyes. Plants inoculated with slow-growing strains 176A22, 176A30, and 176A32 developed a maximum acetylene reduction activity of 24.6, 27.0, and 32 μmol of ethylene formed per plant per h, respectively, versus 6.4 μmol per plant per h in plants inoculated with the fast-growing strain 176A28. When inoculated with approximately equal proportions of rhizobia, the fast-growing strain 176A28 produced 95% of the nodules when challenged with the slow-growing strain 176A22, but formed only 6% of the nodules when challenged with the slow-growing strain 176A30. Consequently, there was no relation between the growth rate in vitro and the capability of rhizobia to compete for nodule-forming sites. Plants inoculated with strain 176A28 and subjected to drought during the vegetative growth period recovered to the same level of nitrogen fixation and nodulation as those that received adequate irrigation. On the other hand, plants inoculated with strains 176A22, 176A30, and 176A32 failed to achieve the same levels of nodulation and nitrogen fixation under drought as compared with irrigated conditions.     

Increased Effectiveness of Competitive Rhizobium Strains upon Inoculation of Cajanus cajan

A field study was conducted in lysimeters containing ¹⁵N-enriched soil to determine the effects of four competitive rhizobium strains upon yield parameters of pigeon peas (Cajanus cajan). The greatest differences observed were in seed yields; strain P132 effected the highest seed yield (121 ± 20 g per plant), and the control strain (indigenous rhizobia) effected the lowest yield (43.9 ± 8 g per plant). With the exception of seeds and pods, the dry matter weights were not different. Although there appeared to be no effect by inoculum strains on the fractional content of N derived from biological nitrogen fixation when the total plant biomass was considered, strains P132 and 401 partitioned more of the N derived from fixation into seeds and leaves than did the other strains. Because the seeds comprised the major portion of plant N, more total N and more N derived from biological nitrogen fixation (about half of total N) were found in plants inoculated with P132, whereas the smallest amount was found in the uninoculated controls. P132 was also the best competitor with respect to indigenous rhizobia and acounted for all of the nodules found on the plants in which it was inoculated.     

An 1-Aminocyclopropane-1-carboxylate (ACC) deaminase-expressing endophyte increases plant resistance to flavescence dorée phytoplasma infection

Flavescence dorée is an epidemic yellows disease of grapevine, caused by a phytoplasma (FDP), for which there is currently no cure. We assessed whether the endophyte Pseudomonas migulae 8R6, able to synthesize 1-aminocyclopropane-1-carboxylate (ACC) deaminase, can limit the phytoplasma-induced damages in periwinkle, a model plant hosting FDP. Plant protection induced by 8R6 and its mutant, impaired in ACC deaminase synthesis, was compared. Fifteen plants per treatment were used; FD infection was transmitted by grafting. Evaluation of symptoms was performed every 4 days for 40 days. The presence and the amount of FDP were assessed by nested PCR and qPCR, respectively. Images of phytoplasma inside the infected plants were obtained by transmission electron microscopy. The strain 8R6 significantly reduced the number of symptomatic plants (53% vs 93%). While the density of FDP inside the leaves was unaffected by the bacterial strains, the FDP titre was under the quantification threshold in 38% of the plants inoculated with strain 8R6. Microscopical observations showed damaged FDP cells in plants inoculated with strain 8R6. The ACC deaminase activity of the endophytic bacteria P. migulae 8R6 helps the plant to regulate the level of the stress-related hormone ethylene, leading to significantly improved resistance to phytoplasma infection.     

Intercellular colonization and growth promoting effects of Methylobacterium sp. with plant-growth regulators on rice (Oryza sativa L. Cv CO-43)

The Methylobacterium sp. strain NPFM-SB3, isolated from Sesbania rostrata stem nodules possessed nitrogenase activity and nodA genes. Pure culture of NPFM-SB3 strain produced indole-3-acetic acid, cytokinins and on inoculation to rice plants resulted in numerous lateral roots. Inoculation of synthetic auxins 2,4-dichlorophenoxy acetic acid, naphthalene acetic acid or flavonoids naringenin and dihydroxy-4-methoxyisoflavone individually or to bacterial inoculated rice seedlings improved the plant growth and lateral root formation under hydroponic condition. The formation of nodule-like structure and nitrogenase activity which is purely auxin dependent was observed in 2,4-dichlorophenoxy acetic acid treatments to Methylobacterium sp. NPFM-SB3 inoculated rice plants. The rhizobia entered through fissures formed due to lateral root emergence and spread intercellularly in the nodular structures concluded that the effect of 2,4-dichlorophenoxy acetic acid treatment for rice seedlings grown under gnotobiotic conditions is to create a niche in which these bacteria can grow.     

Enhanced Nodulation and Nitrogen Fixation by a Revertant of a Nodulation-Defective Bradyrhizobium japonicum Tryptophan Auxotroph

In greenhouse studies, the symbiotic properties of a prototrophic revertant (TA11 NOD⁺) of a nodulation defective tryptophan auxotroph of Bradyrhizobium japonicum were compared with those of the normally nodulating wild-type strain, B. japonicum I-110 ARS. Strain I-110 ARS was the parent of auxotrophic mutant TA11. Plants inoculated with TA11 NOD⁺ contained significantly more nitrogen per plant than did plants inoculated with wild-type bacteria (275.9 ± 35 versus 184 ± 18 mg). Also, plants that received the revertant were larger, averaging 8.4 ± 0.9 g (dry weight) versus 6.4 ± 0.6 g for those that received the wild-type bacterial strain. Additionally, plants that received the NOD⁺ strain had 56% more nodules and 41% more nodule mass than did control plants. With both inocula, average nodule size and amount of nitrogen fixed per gram of nodule were about the same. These data indicated that the improvement in nitrogen fixation observed with the TA11 NOD⁺ resulted from an increase in the overall nodule number. The physiological basis for this increase in nodulation is not known, but enhanced tryptophan catabolism does not appear to be involved.     

Rhizostabilization of metals in soils using Lupinus luteus inoculated with the metal resistant rhizobacterium Serratia sp. MSMC541

The aim of this work was to test Lupinus luteus plants, inoculated with metal resistant rhizobacteria, in order to phytostabilise metals in contaminated soils. The resistance to heavy metals of strains isolated from nodules of Lupinus plants was evaluated. The strain MSMC541 showed multi-resistance to several metals (up to 13.3 mM As, 2.2 mM Cd, 2.3 mM Cu, 9 mM Pb and 30 mM Zn), and it was selected for further characterization. Furthermore, this strain was able to biosorb great amounts of metals in cell biomass. 16S rDNA sequencing positioned this strain within the genus Serratia. The presence of arsenic resistance genes was confirmed by southern blot and PCR amplification. A rhizoremediation pot experiment was conducted using Lupinus luteus grown on sand supplemented with heavy metals and inoculated with MSMC541. Plant growth parameters and metal accumulation were determined in inoculated vs. non-inoculated Lupinus luteus plants. The results showed that inoculation with MSMC541 improved the plant tolerance to metals. At the same time, metal translocation to the shoot was significantly reduced upon inoculation. These results suggest that Lupinus luteus plants, inoculated with the metal resistant strain Serratia sp. MSMC541, have a great potential for phytostabilization of metal contaminated soils.     

Genetically marked Rhizobium identifiable as inoculum strain in nodules of soybean plants grown in fields populated with Rhizobium japonicum.

The fate of an inoculum strain of Rhizobium japonicum was studied using a genetically marked strain I-11O subline carrying resistance markers for azide, rifampin, and streptomycin (I-110 ARS). At the time of planting into a field populated with R. japonicum, seeds of soybean cultivars Kent and Peking were inoculated with varying cell densities of strain I-110 ARS. At various times during the growing season, surface-sterilized root nodules were examined for the presence of the inoculum strain by plating onto selective media. The recovery of the inoculum strain was unambiguous, varying, in the case of Kent cultivar, from about 5% with plants (sampled at 51 days) that had been inoculated with 3 X 10(8) cells per cm of row to about 20% with plants (sampled at 90 days) that had been inoculated with 3 X 10(9) cells per cm. The symbiotically incompatible interaction of Peking and strain 110 in Rhizobium-populated field soil was confirmed by the finding that at 60 days after planting, only one nodule in 360 sampled contained strain I-110 ARS. The use of genetically marked Rhizobium bacteria was found to provide for precise identification of the inoculum strain in nodules of field-grown soybeans.     

Quantitative assessments of the host range and strain specificity of endophytic colonization by Klebsiella pneumoniae 342

Enteric bacteria, particularly Klebsiella, are common endophytes of plants. Endophytic colonization is important as these bacteria may be beneficial, either by providing fixed N or growth hormones to the host plant. In this work, we assessed the host range and strain specificity for endophytic colonization with Klebsiella pneumoniae 342 (Kp342) on five host plants. This strain was inoculated onto seedlings of Medicago sativa, Medicago truncatula, Arabidopsis thaliana, Triticum aestivum, and Oryza sativa. The type strain of K. pneumoniae, ATCC13883, was also inoculated on all of these hosts except M. truncatula. Both strains were labeled with GFP. Eight inoculum levels were used from 1 CFU to 10⁷ CFU per plant plus uninoculated controls. Six days after inoculation, the number of cells colonizing the rhizosphere and interior were determined. Inoculation with about one CFU of Kp342 was adequate to obtain high colonization levels on the rhizosphere and roots of all host plants. The type strain could colonize the interior of the host plant but the highest colonization levels were generally 100-fold lower than those obtained from Kp342 and those levels required at least 1000 cells in the inoculum. Thus, Kp342 was a more efficient colonizer of the plant apoplast. In addition, the monocots inoculated in this work were colonized endophytically in much higher numbers than were the dicots. Cells of Kp342 congregate at lateral root junctions suggesting the cells enter the plant through cracks created by lateral root extensions. The strain and host effects observed here suggest that endophytic colonization is an active process controlled by genetic determinants from both partners.     

Genetically marked Rhizobium identifiable as inoculum strain in nodules of soybean plants grown in fields populated with Rhizobium japonicum

The fate of an inoculum strain of Rhizobium japonicum was studied using a genetically marked strain I-11O subline carrying resistance markers for azide, rifampin, and streptomycin (I-110 ARS). At the time of planting into a field populated with R. japonicum, seeds of soybean cultivars Kent and Peking were inoculated with varying cell densities of strain I-110 ARS. At various times during the growing season, surface-sterilized root nodules were examined for the presence of the inoculum strain by plating onto selective media. The recovery of the inoculum strain was unambiguous, varying, in the case of Kent cultivar, from about 5% with plants (sampled at 51 days) that had been inoculated with 3 X 10(8) cells per cm of row to about 20% with plants (sampled at 90 days) that had been inoculated with 3 X 10(9) cells per cm. The symbiotically incompatible interaction of Peking and strain 110 in Rhizobium-populated field soil was confirmed by the finding that at 60 days after planting, only one nodule in 360 sampled contained strain I-110 ARS. The use of genetically marked Rhizobium bacteria was found to provide for precise identification of the inoculum strain in nodules of field-grown soybeans.     

Improvement of drought tolerance and grain yield in common bean by overexpressing trehalose-6-phosphate synthase in rhizobia

Improving stress tolerance and yield in crops are major goals for agriculture. Here, we show a new strategy to increase drought tolerance and yield in legumes by overexpressing trehalose-6-phosphate synthase in the symbiotic bacterium Rhizobium etli. Phaseolus vulgaris (common beans) plants inoculated with R. etli overexpressing trehalose-6-phosphate synthase gene had more nodules with increased nitrogenase activity and higher biomass compared with plants inoculated with wild-type R. etli. In contrast, plants inoculated with an R. etli mutant in trehalose-6-phosphate synthase gene had fewer nodules and less nitrogenase activity and biomass. Three-week-old plants subjected to drought stress fully recovered whereas plants inoculated with a wild-type or mutant strain wilted and died. The yield of bean plants inoculated with R. etli overexpressing trehalose-6-phosphate synthase gene and grown with constant irrigation increased more than 50%. Macroarray analysis of 7,200 expressed sequence tags from nodules of plants inoculated with the strain overexpressing trehalose-6-phosphate synthase gene revealed upregulation of genes involved in stress tolerance and carbon and nitrogen metabolism, suggesting a signaling mechanism for trehalose. Thus, trehalose metabolism in rhizobia is key for signaling plant growth, yield, and adaptation to abiotic stress, and its manipulation has a major agronomical impact on leguminous plants.     

Colored Mulches Affect Yield of Fresh-market Tomato Infected with Meloidogyne incognita

The effects of different-colored polyethylene mulches on the quantity and spectra of reflected light, earliness of fruit set, fruit yield and quality, and root-knot disease were studied in field-grown, staked tomato (Lycopersicon esculentum). White mulch reflected more photosynthetic light and a lower far-red-to-red ratio than red mulch, whereas black mulch reflected less than 5 percent of any color. Soil temperatures and fruit yields were recorded for tomato plants inoculated with Meloidogyne incognita race 3 at initial populations of 0, 1,000, 10,000, 50,000, or 100,000 eggs/plant and grown over black, white, or red plastic mulch in both spring and fall. Soil temperatures were lower under white mulch than under red or black mulch. Tomato yields declined as inoculum level increased. Plants grown over red mulch in the spring and inoculated with 50,000 eggs of M. incognita had greater early marketable yields than similarly inoculated plants grown over black or white mulch. Tomato plants inoculated with 100,000 eggs and grown over white mulch or red mulch in the spring had greater total yields per plot than similar plants grown over black mulch (7.39 kg and 7.71 kg vs. 3.65 kg, respectively).     

Field Studies on Cross-protection against Japanese yam mosaic virus in Chinese yam (Dioscorea opposita) with an Attenuated Strain of the Virus

An attenuated strain of Japanese yam mosaic virus (JYMV), designated T‐3, was evaluated for its cross‐protection efficacy against virulent (native) strains of JYMV in Chinese yam (Dioscorea opposita) grown in farmers’ fields in Japan. Native strains of JYMV were detected by a polymerase chain reaction‐based assay in all the Chinese yam plants grown from virus‐free tubers in the first growing season in the fields. In contrast, the virus was detected in only one of fifty plants grown from tubers preinoculated with T‐3 during the experiments for 6 years, suggesting that T‐3 consistently cross‐protected against native JYMV in Chinese yam in the field. Chinese yam plants preinoculated with T‐3 produced significantly greater yield of tubers per plant compared with non‐inoculated plants.     

Production and function of jasmonates in nodulated roots of soybean plants inoculated with Bradyrhizobium japonicum

Little is known regarding production and function of endogenous jasmonates (JAs) in root nodules of soybean plants inoculated with Bradyrhizobium japonicum. We investigated (1) production of jasmonic acid (JA) and 12-oxophytodienoic acid (OPDA) in roots of control and inoculated plants and in isolated nodules; (2) correlations between JAs levels, nodule number, and plant growth during the symbiotic process; and (3) effects of exogenous JA and OPDA on nodule cell number and size. In roots of control plants, JA and OPDA levels reached a maximum at day 18 after inoculation; OPDA level was 1.24 times that of JA. In roots of inoculated plants, OPDA peaked at day 15, whereas JA level did not change appreciably. Shoot dry matter of inoculated plants was higher than that of control at day 21. Chlorophyll a decreased more abruptly in control plants than in inoculated plants, whereas b decreased gradually in both cases. Exogenous JA or OPDA changed number and size of nodule central cells and peripheral cells. Findings from this and previous studies suggest that increased levels of JA and OPDA in control plants are related to senescence induced by nutritional stress. OPDA accumulation in nodulated roots suggests its involvement in "autoregulation of nodulation."     

Increase in Internode Length of Phaseolus lunatus L. Caused by Inoculation with a Nitrate Reductase-deficient Strain of Rhizobium sp

Dramatic differences in the height of lima beans (Phaseolus lunatus L.) treated with two different Rhizobium strains were studied. Lima beans were grown in Perlite in the greenhouse or in a minus-N culture solution in the growth chamber. The plants were inoculated with either Rhizobium sp. (lima bean) strain 127E15, which contains the constitutive nitrate reductase activity, or strain 127E14, which lacks that activity. For up to 3 weeks, no growth differences were observed in the plants inoculated with either strain. Five weeks after inoculation, however, those plants inoculated with strain 127E14 were significantly taller and had a larger number of leaves than those inoculated with strain 127E15. The difference in plant height was the result of increased internode elongation caused by inoculation with Rhizobium sp. 127E14. This response was observed with all lima bean cultivars tested, including Henderson, Fordhook, Allgreen, and Early Thorogreen. The growth difference occurred in plants cultured in the greenhouse or in the growth chamber.     

Rhizobitoxine production and symbiotic compatibility of Bradyrhizobium from Asian and North American lineages of amphicarpaea.

Reciprocal inoculations with Bradyrhizobium sp. isolates from the North American legume Amphicarpaea bracteata (L.) Fern. (Phaseoleae-Glycininae) and from a Japanese population of its close relative Amphicarpaea edgeworthii (Benth.) var. japonica were performed to analyze relative symbiotic compatibility. Amphicarpaea edgeworthii plants formed few or no nodules with any North American bradyrhizobial strains isolated from A. bracteata, but all A. bracteata lineages formed effective nitrogen-fixing nodules with Japanese Bradyrhizobium isolates from A. edgeworthii. However, one group of A. bracteata plants (lineage Ia) when inoculated with Japanese bradyrhizobia developed a striking leaf chlorosis similar to that known to be caused by rhizobitoxine. The beta-cystathionase inhibition assay demonstrated that significant amounts of rhizobitoxine were present in nodules formed by these Japanese bradyrhizobia. No North American bradyrhizobial isolate from A. bracteata induced chlorosis on any plants, and the beta-cystathionase assay failed to detect rhizobitoxine in nodules formed by these isolates. The role of rhizobitoxine in A. edgeworthii nodulation development was tested by inoculating plants with a Bradyrhizobium elkanii rhizobitoxine-producing strain, USDA 61, and two mutant derivatives, RX17E and RX18E, which are unable to synthesize rhizobitoxine. Amphicarpaea edgeworthii inoculated with wild-type USDA 61 developed >150 nodules per plant, while plants inoculated with RX17E and RX18E developed fewer than 10 nodules per plant. Thus, efficient nodule development in A. edgeworthii appears to be highly dependent on rhizobitoxine production by Bradyrhizobium strains.