Interactions between Azotobacter chroococcum and vesicular-arbuscular mycorrhiza and their effects on plant growth

B rown , M. E. & G arr , G. R. 1984 Interactions between Azotobacter chroo-coccum and vesicular-arbuscular mycorrhiza and their effects on plant growth. Journal of Applied Bacteriology 56 , 429–437.
The effects of simultaneous inoculation of roots of lettuce seedlings with vesicular-arbuscular endophytes and Azotobacter chroococcum are described. Endophytes alone increased yields of lettuce grown in partially sterilized P-deficient soil, but not in the same unsterile soil. Dual inoculation with endophytes and Azotobacter in both soils produced larger plants than either inoculum alone. In another poorly structured unsterile soil with adequate P for plant growth, endophytes depressed yields of lettuce. There was no association between endophytes and Azotobacter . In none of the experiments did Azotobacter influence the level of endophyte infection in the roots; but numbers of Azotobacter on the root systems were decreased in the presence of the endophytes. Azotobacter alone always increased growth of young plants before the effects of the endophytes were observed.     

烟草根际微生物研究

利用选择性培养基,对土壤肥力肥沃、中等、贫瘠的烟区根际细菌、真菌和放线菌进行了分离和测数。根据菌体形态及培养特征、生理生化指标及16S rDNA部分序列分析等,对根际自生固氮菌、磷细菌、钾细菌进行了鉴定和分类。主要结果为：土壤肥沃的烟区根际细菌的数量最多,土壤贫瘠的烟区数量最少;土壤贫瘠烟区根际真菌的数量较多,中等和肥沃烟区的较少;根际故线菌的数量随土壤肥力的降低而依次减小。从不同肥力烟区分离的根际自生固氮菌、磷细菌、钾细菌以革兰氏阴性杆菌为主,分别属于10个属。土壤的肥沃程度对根际3类细菌的种类和数量都有影响,总体上看,土壤肥沃和中等的条件下,细菌类群的多样性和丰富度较大,而贫瘠土壤细菌类群的优势度较大。     

The effectivity of arbuscular mycorrhizal fungi from high input conventional and organic grassland and grass-arable rotations

The effectivity of arbuscular mycorrhizal spores in promoting growth of Allium ameloprasum L. cv. Musselburgh and Trifolium repens L. cv. Menna was tested for inocula from three soil series under long term organic or intensive, conventional grass and grass-arable rotations. For two soil series, Allium responses to inocula from soils recently converted to organic fanning were also assessed. Finally, Trifolium root fragments were used to inoculate Allium so as to evaluate responses to this inoculation procedure. Plants were sown into previously sterilised, matched soils from organic farms with no nutrient input. Mycorrhizal treatments generally increased growth for Allium. However, for Trifolium, infection decreased growth in the most fertile soil and gave an increase only in the least fertile. In the least fertile soil, inocula from organic farms were more effective than those from conventional farms. For Trifolium (all soils) and for Allium (least fertile soil), there was evidence of more efficient uptake of phosphorus in plants inoculated with spores from organic farms. The pattern of Allium response to inoculation with spores from conventional, conversion and organic sources was not consistent between soil type, but there was evidence of lower root infection for conversion compared with organic inocula and of a trend towards higher infectivity as the time period under organic management increased. Inoculating Allium with AMF root fragments produced a plant response similar to that obtained when spores were used, confirming that spore viability was not the sole factor influencing AMF effectivity in earlier experiments. Intensive farming practices may reduce the effectiveness of indigenous arbuscular mycorrhizal populations, particularly where fertiliser inputs are high and inherent fertility is low. This could have practical implications where high input farms are converted to organic management.     

Improvement of Arbuscular Mycorrhiza Development by Inoculation of Soil with Phosphate-Solubilizing Rhizobacteria To Improve Rock Phosphate Bioavailability ((sup32)P) and Nutrient Cycling

The interactive effect of phosphate-solubilizing bacteria and arbuscular mycorrhizal (AM) fungi on plant use of soil P sources of low bioavailability (endogenous or added as rock phosphate [RP] material) was evaluated by using soil microcosms which integrated (sup32)P isotopic dilution techniques. The microbial inocula consisted of the AM fungus Glomus intraradices and two phosphate-solubilizing rhizobacterial isolates: Enterobacter sp. and Bacillus subtilis. These rhizobacteria behaved as "mycorrhiza helper bacteria" promoting establishment of both the indigenous and the introduced AM endophytes despite a gradual decrease in bacterial population size, which dropped from 10(sup7) at planting to 10(sup3) CFU g(sup-1) of dry rhizosphere soil at harvest. Dual inoculation with G. intraradices and B. subtilis significantly increased biomass and N and P accumulation in plant tissues. Regardless of the rhizobacterium strain and of the addition of RP, AM plants displayed lower specific activity ((sup32)P/(sup31)P) than their comparable controls, suggesting that the plants used P sources not available in their absence. The inoculated rhizobacteria may have released phosphate ions ((sup31)P), either from the added RP or from the less-available indigenous P sources, which were effectively taken up by the external AM mycelium. Soluble Ca deficiency in the test soil may have benefited P solubilization. At least 75% of the P in dually inoculated plants derived from the added RP. It appears that these mycorrhizosphere interactions between bacterial and fungal plant associates contributed to the biogeochemical P cycling, thus promoting a sustainable nutrient supply to plants.     

Structure and ecological function of the soil microbiome affecting plant–soil feedbacks in the presence of a soil-borne pathogen

Interactions between plants and soil microbes are important for plant growth and resistance. Through plant–soil-feedbacks, growth of a plant is influenced by the previous plant that was growing in the same soil. We performed a plant–soil feedback study with 37 grass, forb and legume species, to condition the soil and then tested the effects of plant-induced changes in soil microbiomes on the growth of the commercially important cut-flower Chrysanthemum in presence and absence of a pathogen. We analysed the fungal and bacterial communities in these soils using next-generation sequencing and examined their relationship with plant growth in inoculated soils with or without the root pathogen, Pythium ultimum. We show that a large part of the soil microbiome is plant species-specific while a smaller part is conserved at the plant family level. We further identified clusters of plant species creating plant growth promoting microbiomes that suppress concomitantly plant pathogens. Especially soil inocula with higher relative abundances of arbuscular mycorrhizal fungi caused positive effects on the Chrysanthemum growth when exposed to the pathogen. We conclude that plants differ greatly in how they influence the soil microbiome and that plant growth and protection against pathogens is associated with a complex soil microbial community.     

纤维素分解菌与无机磷细菌的相互作用

大多数土壤全磷含量较高 ,但由于其固定能力很强 ,不仅有效磷含量较低 ,而且施入的水溶性磷肥很快转化为无效形态。活化土壤中无效磷库 ,提高其有效性 ,是一个具有重要实践意义的研究课题。研究结果表明 ,土壤中存在许多具活化无效磷功能的微生物 ,尤其在根际土壤中解磷微生物的数量比非根际要多[8] ,这些微生物统称为解磷菌。增加土壤或根际解磷菌的数量 ,就能活化土壤中的无效磷 ,提高磷的利用率。但土壤中的解磷菌大多数是腐生性的 ,其生长繁殖需要碳源 ,而多数情况下 ,土壤碳源很少 ,且主要是农作物残体 ,其主要成分是纤维素和半纤维素 …     

Influence of eggs,juveniles and cysts as types of inocula on viability,infectivity and virulence of Heterodera zeae on corn in Egypt

The effect of different sources of inocula, i.e. eggs, juveniles and cysts on the development, reproduction and virulence of the corn cyst nematode, Heterodera zeae infected corn cv. Giza 2 under greenhouse conditions (30?±?5?°C) revealed that the lowest final population and rate of build-up of the nematode were detected in those plants inoculated with juveniles; while the maximum values were obtained by eggs when used as initial inocula. Hence, the percentage of reduction in Giza 2 corn growth parameters were more pronounced in plants which had been inoculated with eggs as inocula comparing with those plants inoculated either by cysts or by juveniles.     

Formation of artificial nitrogen-fixing symbiosis with rape (Brassica napus var. napus) plants in nonsterile soil]

The treatment of rape plants grown in nonsterile soil with 2,4-dichlorophenoxyacetic acid (auxin-like growth-promoting substance) or their inoculation with the bacterial association Micrococcus sp. + Rhodococcus sp. and/or with the mixed nitrogen-fixing culture Azotobacter nigricans + Bacillus sp. led to the formation of paranodules on the rape roots. The introduced bacteria were detected both in the intercellular space and inside the cells of the paranodules and the rape roots. The nitrogen-fixing activity of the paranodulated plants was two times higher than that of the inoculated plants lacking paranodules and five times higher than that of the control (i.e., not inoculated) plants. The paranodulation led to a 40% increase in the crop yield of rape plants and provided for a statistically significant increase in the total nitrogen as well as protein nitrogen contents of the plants.     

Importance of Inoculum Properties on the Structure and Growth of Bacterial Communities during Recolonisation of Humus Soil with Different pH

The relationship between community structure and growth and pH tolerance of a soil bacterial community was studied after liming in a reciprocal inoculum study. An unlimed (UL) humus soil with a pH of 4.0 was fumigated with chloroform for 4 h, after which ?<?1 % of the initial bacterial activity remained. Half of the fumigated soil was experimentally limed (EL) to a pH of 7.6. Both the UL and the EL soil were then reciprocally inoculated with UL soil or field limed (FL) soil with a pH of 6.2. The FL soil was from a 15-year-old experiment. The structural changes were measured on both bacteria in soil and on bacteria able to grow on agar plates using phospholipids fatty acid (PLFA) and denaturing gradient gel electrophoresis (DGGE) analysis. The developing community pH tolerance and bacterial growth were also monitored over time using thymidine incorporation. The inoculum source had a significant impact on both growth and pH tolerance of the bacterial community in the EL soil. These differences between the EL soil inoculated with UL soil and FL soil were correlated to structural changes, as evidenced by both PLFA and DGGE analyses on the soil. Similar correlations were seen to the fraction of the community growing on agar plates. There were, however, no differences between the soil bacterial communities in the unlimed soils with different inocula. This study showed the connection between the development of function (growth), community properties (pH tolerance) and the structure of the bacterial community. It also highlighted the importance of both the initial properties of the community and the selection pressure after environmental changes in shaping the resulting microbial community.     

Evaluation of fly ash as a carrier for diazotrophs and phosphobacteria

Fly ash and its different combinations with soil (w/w) were tested to explore its possible use as a potential carrier for diazotrophs and phosphobacteria. Azotobacter chroococcum, Azospirillum brasilense and Bacillus circulans showed their maximum viability in fly ash alone whereas Pseudomonas striata proliferated most in soil:fly ash (1:1) combination.     

The Formation of Artificial Nitrogen-Fixing Symbioses with Rape (Brassica napusvar. napus) Plants in Nonsterile Soil

The treatment of rape plants grown in nonsterile soil with 2,4-dichlorophenoxyacetic acid (auxin-like growth-promoting substance) or their inoculation with the bacterial association Micrococcussp. + Rhodococcussp. and/or with the mixed nitrogen-fixing culture Azotobacter nigricans+ Bacillussp. led to the formation of paranodules on the rape roots. The introduced bacteria were detected both in the intercellular space and inside the cells of the paranodules and the rape roots. The nitrogen-fixing activity of the paranodulated plants was two times higher than that of the inoculated plants lacking paranodules and five times higher than that of the control (i.e., not inoculated) plants. The paranodulation led to a 40% increase in the crop yield of rape plants and provided for a statistically significant increase in the total nitrogen as well as protein nitrogen contents of the plants.     

Ability of bacterium Bacillus subtilis to produce cytokinins and to influence the growth and endogenous hormone content of lettuce plants

Hormone production by micro-organisms selected as antagonists of pathogenic fungi and the effect of their introduction into soil on hormone content and growth of lettuce plants were studied. Hormones in bacterial cultural media and in plant extracts were immunopurified and assayed using specific antibodies to indolyl-3-acetic acid (IAA), abscisic acid (ABA), and different cytokinins (zeatin riboside (ZR), dihydrozeatinriboside (DHZR) and isopentenyladenosine (iPA)). ZR was shown to be the main cytokinin present in bacterial cultural media as a complex with a high molecular weight component. Inoculation of lettuce plants with bacteria increased the cytokinin content of both shoots and roots. Accumulation of zeatin and its riboside was greatest in roots shortly 2days after inoculation, when their content was 10 times higher than in control. Changes in the content of other hormones (ABA and IAA) were observed at the end of experiments only. Accumulation of cytokinins in inoculated lettuce plants was associated with an increase in plant shoot and root weight of approximately 30% over 8days.     

Effects on plant growth of inoculation of stored stripmining topsoil in North Dakota with mycorrhizal fungi contained in native soils

Stored topsoil from stripmining operations in western North Dakota was inoculated with mycorrhizal fungi contained in native prairie soil. The effects on plant mycorrhizal infection percentage, growth as shoot dry weight, and phosphorus uptake were determined. The studied topsoil piles were found to contain little or no vesicular arbuscular mycorrhizal (VAM) fungal inoculum at a depth of 120 cm. The inoculum soil was mixed into the stored soil at rates of 10% and 1%, or surface-applied at 1%. In control pots, sterilized inoculum soil was used. Corn plant (Zea mays) bioassays were used. After 30 days growth the percent VAM fungal infection of the test plants increased with both the 10% and 1% soil inocula. Phosphorus concentrations were generally increased by inoculation with 10% soil mixtures but not 1%. Shoot dry weights of the plants were not measurably different between 10% and 1% inoculation. However, when the plant growth period was increased to 60 days, all three parameters were increased over the check plants. When the inoculum was not mixed into the soil, but layered on the surface, there were no differences in any of the parameters.     

The effects of temporal variation in soil carbon inputs on resource allocation in an annual plant

Aims Resource allocation in plants can be strongly affected by competition. Besides plant–plant interactions, terrestrial plants compete with the soil bacterial community over nutrients. Since the bacterial communities cannot synthesize their own energy sources, they are dependent on external carbon sources. Unlike the effect of overall amounts of carbon (added to the soil) on plant performance, the effect of fine scale temporal variation in soil carbon inputs on the bacterial biomass and its cascading effects on plant growth are largely unknown. We hypothesize that continuous carbon supply (small temporal variance) will result in a relatively constant bacterial biomass that will effectively compete with plants for nutrients. On the other hand, carbon pulses (large temporal variance) are expected to cause oscillations in bacterial biomass, enabling plants temporal escape from competition and possibly enabling increased growth. We thus predicted that continuous carbon supply would increase root allocation at the expense of decreased reproductive output. We also expected this effect to be noticeable only when sufficient nutrients were present in the soil.Methods Wheat plants were grown for 64 days in pots containing either sterilized or inoculated soils, with or without slow-release fertilizer, subjected to one of the following six carbon treatments: daily (1.5mg glucose), every other day (3mg glucose), 4 days (6mg glucose), 8 days (12mg glucose), 16 days (24mg glucose) and no carbon control.Important findings Remarkably, carbon pulses (every 2–16 days) led to increased reproductive allocation at the expense of decreased root allocation in plants growing in inoculated soils. Consistent with our prediction, these effects were noticeable only when sufficient nutrients were present in the soil. Furthermore, soil inoculation in plants subjected to low nutrient availability resulted in decreased total plant biomass. We interpret this to mean that when the amount of available nutrients is low, these nutrients are mainly used by the bacterial community. Our results show that temporal variation in soil carbon inputs may play an important role in aboveground–belowground interactions, affecting plant resource allocation.     

Micro-organisms in the rhizosphere of plants inoculated withAzotobacter chroococcum

Summary The hypothesis that inoculation withAzotobacter chroococcum affects the growth of plants indirectly through changing the rhizosphere microflora was investigated. Inoculated and uninoculated wheat and tomato plants were grown in the glasshouse in two different soils, and total bacteria, chitinolytic bacteria, actinomycetes, glucosefermenting bacteria, aerobic cellulose-decomposing bacteria, and anaerobes were determined in intervals in the rhizosphere and in the soil. Root-surface fungi were studied using the Harley and Waid's root-washing technique¹⁰. Azotobacter became established in the rhizosphere of wheat and tomato plants and stimulated their growth. All the bacterial groups examined were more abundant in the rhizosphere than in the soil. Inoculation with Azotobacter delayed the colonization of roots by bacteria, actinomycetes, and fungi in the rhizosphere, but had no effect on other organisms. Inoculation did not affect the dominant root-surface fungi, and minor changes were not consistent.Part of a thesis accepted by the University of London for the degree of Ph.D. in Microbiology.     

Salinity effects on germination,growth, and seed production of the halophyte Cakile maritima

The growth ofEucalyptus regnans seedlings in forest soil is enhanced when it has been air-dried. In undried forest soil seedlings grow poorly and develop purple coloration in the foliage, indicating P deficiency. This paper reports the results of pot experiments designed to investigate the relationship between growth and P acquisition, ectomycorrhizal infection and age of seedlings grown in air-dried and undried soil. The effect on seedling growth of their inoculation with air-dried or undried soil or with ectomycorrhizal roots from plants growing in air-dried or undried soil was also investigated. Ectomycorrhizal root tips were detected in 3-week-oldE. regnans seedlings in both air-dried and undried soil, and from then on the frequency of ectomycorrhizal root tips increased rapidly. In air-dried soil, seedlings were fully ectomycorrhizal at 9 weeks, and the occurrence of maximum ectomycorrhizal infection coincided with enhanced P acquisition and the initiation of rapid seedling growth. In undried forest soil, seedling growth remained poor, even though the seedlings had well-developed ectomycorrhizae and the incidence of ectomycorrhizal root tips was the same as in air-dried soil. The dominant ectomycorrhizae in airdried soil were associated with an ascomycete fungus, whereas in undried, undisturbed soil they were commonly associated with basidiomycete fungi. Inoculation of sterile soil/sand mix with washed ectomycorrhizal roots from air-dried soil increased the P acquisition and growth of the seedlings significantly compared with controls, whereas ectomycorrhizal inocula from undried soil had no effect on seedling growth, although both inocula resulted in a similar incidence of ectomycorrhizal root tips. Similarly, addition of a small amount of air-dried soil into sterile soil/sand mix resulted in a significantly greater increase in the P content and dry weight of the seedlings, compared with the control, than addition of undried soil. In both treatments, the incidence of ectomycorrhial root tips was similar. As (i) the differentiation in seedling growth between air-dried and undried soil occurred after seedlings became ectomycorrhizal, (ii) the dominant ectomycorrhizae in air-dried soil were different from those in undried soil, and (iii) inocula from air-dried soil, but not from undried soil, stimulated seedling growth in sterile soil/sand mix, it is concluded that development of particular ectomycorrhizae may be involved in seedling growth stimulation and enhanced P acquisition associated with air drying of forest soil.     

Arbuscular mycorrhizal infection changes the bacterial 16 S rDNA community composition in the rhizosphere of maize

Mycorrhizal and non-mycorrhizal (NM) maize plants were grown for 4 or 7 weeks in an autoclaved quartz sand-soil mix. Half of the NM plants were supplied with soluble P (NM-HP) while the other half (NM-LP), like the mycorrhizal plants, received poorly soluble Fe and Al phosphate. The mycorrhizal plants were inoculated with Glomus mosseae or G. intraradices. Soil bacteria and those associated with the mycorrhizal inoculum were reintroduced by adding a filtrate of a low P soil and of the inocula. At 4 and 7 weeks, plants were harvested and root samples were taken from the root tip (0-1 cm), the subapical zone (1-2 cm) and the mature root zone at the site of lateral root emergence. DNA was extracted from the roots with adhering soil. At both harvests, the NM-HP plants had higher shoot dry weight than the plants grown on poorly soluble P. Mycorrhizal infection of both fungi ranged between 78% and 93% and had no effect on shoot growth or shoot P content. Eubacterial community compositions were examined by polymerase chain reaction-denaturing gradient gel electrophoresis of 16 S rDNA, digitisation of the band patterns and multivariate analysis. The community composition changed with time and was root zone specific. The differences in bacterial community composition in the rhizosphere between the NM plants and the mycorrhizal plants were greater at 7 than at 4 weeks. The two fungi had similar bacterial communities after 4 weeks, but these differed after 7 weeks. The observed differences are probably due to changes in substrate composition and amount in the rhizosphere.     

Establishment and impact of Pseudomonas fluorescens genetically modified for lactose utilization and kanamycin resistance in the rhizosphere of pea

The impact of a Pseudomonas fluorescens strain, genetically modified for kanamycin resistance and lactose utilization (the GMM), could be enhanced by soil amendment with lactose and kanamycin. Lactose addition decreased the shoot to root ratio of pea, and both soil amendments increased the populations of total culturable bacteria and the inoculated GMM. Only kanamycin perturbed the bacterial community structure, causing a shift towards slower growth organisms. The community structure with the GMM inocula in the presence of kanamycin showed the only impact of the GMM compared to the wild type inocula. The shift towards K strategy (slower growing organisms), found in the other kanamycin-amended treatments, was reduced with the GMM inoculation. Lactose amendment increased the acid and alkaline phosphatase, the phosphodiesterase activity and the carbon cycle enzyme activities, whereas the kanamycin addition only affected the alkaline phosphatase and phosphodiesterase activities. None of the soil enzyme activities was affected by the GMM under any of the soil amendments.     

Variation in Preference for Rhizobium meliloti Within and Between Medicago sativa Cultivars Grown in Soil

Variation in nodulation preferences for Rhizobium strains within and between Medicago sativa cultivars was assessed in the greenhouse with plants grown in Leonard jars and two soils of diverse origin (Lanark and Ottawa), using inocula consisting of effective individual or paired strains of R. meliloti which could be recognized by high-concentration antibiotic resistance. The results indicated considerable variability in host preferences for R. meliloti among plants within cultivars but not between cultivars. The implications of this variation are discussed from the point of view of possible improvement of symbiotic nitrogen fixation. With one exception, the differences in nodulation success between inoculant R. meliloti strains were consistent in Leonard jars and both soils. All introduced strains formed significantly more nodules in Renfrew soil containing few native rhizobia than in Ottawa soil with a large resident R. meliloti population. Plants grown in Lanark soil without inoculation were ineffectively nodulated by native rhizobia and yielded significantly less growth than those receiving inoculation. In contrast, the yield of inoculated plants in Ottawa soil did not significantly differ from those without inoculation due to effective nodulation by native R. meliloti. The data indicated synergistic effects on yield by certain paired strain inocula relative to the same strains inoculated individually in Lanark but not in Ottawa soil or Leonard jars.