Performance evaluation of potent phosphate solubilizing bacteria in potato rhizosphere

Three phosphate solubilizing bacterial isolates identified as Pantoea agglomerans strain P5, Microbacterium laevaniformans strain P7 and Pseudomonas putida strain P13 were assessed for mutual relationships among them, competitiveness with soil microorganisms and associations with plant root using luxAB reporter genes for follow-up studies. Synergism between either P. agglomerans or M. laevaniformans, as acid-producing bacteria, and P. putida, as a strong phosphatase producer, was consistently observed both in liquid culture medium and in root rhizosphere. All laboratory, greenhouse and field experiments proved that these three isolates compete well with naturally occurring soil microorganisms. Consistently, the combinations of either P. agglomerans or M. laevaniformans strains with Pseudomonas putida led to higher biomass and potato tuber in greenhouse and in field trials. It is conceivable that combinations of an acid- and a phosphatase-producing bacterium would allow simultaneous utilization of both inorganic and organic phosphorus compounds preserving the soil structure.     

Organic Acid Secretion and Phosphate Solubilizing Efficiency of Pseudomonas sp. PSB12: Effects of Phosphorus Forms and Carbon Sources

Secretion of organic acids is an important mechanism for phosphate solubilizing bacteria (PSB) to dissolve insoluble phosphorus in soil. However, the composition of organic acids produced by PSB in the presence of different phosphorus compounds is poorly known, and little is known about the ability of PSB to degrade pollutants in sediment. In this study, we isolated a strain Pseudomonas sp. PSB12 from the sediment of the Qihe River. PSB12 had maximum phosphate solubilization index (SI) of 3.86 on Pikovskaya's agar medium. The phosphate solubilizing activity was associated with the release of organic acids produced from glucose, while the composition of organic acids produced by PSB12 was dependent on the phosphorus forms. When initial soluble phosphorus was insufficient (in MP1 and MP2 media), gluconic acid was the predominant organic acid. In contrast, formic acid, butyrate, and propanedioic acid were the main organic acids produced when only soluble phosphorus (MP3) was supplied. RT-PCR indicated that the expression of glucose dehydrogenase gene (gcd) of PSB12 was two- to four-fold higher in MP1 than in MP3. PSB12 also possessed the phenol hydroxylase gene (phe) suggesting that phenol could be used as the carbon source to dissolve insoluble phosphorus. PSB12 is a potential candidate for in situ bioremediation and for promoting plant growth in soil contaminated by phenol with low levels of soluble phosphorus.     

Establishment of phosphate-solubilizing strains of Azotobacter chroococcum in the rhizosphere and their effect on wheat cultivars under green house conditions

A pot experiment was conducted in the green house to investigate the establishment of phosphate solubilizing strains of Azotobacter chroococcum, including soil isolates and their mutants, in the rhizosphere and their effect on growth parameters and root biomass of three genetically divergent wheat cultivars (Triticum aestivum L.). Five fertilizer treatments were performed: Control, 90 kg N ha^—1, 90 kg N + 60 kg P₂O₅ ha^—1, 120 kg N ha^—1 and 120 kg N + 60 kg P₂O₅ ha^—1. Phosphate solubilizing and phytohormone producing parent soil isolates and mutant strains of A. chroococcum were isolated and selected by an enrichment method. In vitro phosphate solubilization and growth hormone production by mutant strains was increased compared with soil isolates. Seed inoculation of wheat varieties with P solubilizing and phytohormone producing A. chroococcum showed better response compared with controls. Mutant strains of A. chroococcum showed higher increase in grain (12.6%) and straw (11.4%) yield over control and their survival (12—14%) in the rhizosphere as compared to their parent soil isolate (P4). Mutant strain M37 performed better in all three varieties in terms of increase in grain yield (14.0%) and root biomass (11.4%) over control.     

Characterisation of Phosphate Solubilising Bacteria in Sandy Loam Soil Under Chickpea Cropping System

With the aim to explore the possible role of phosphate-solubilizing bacteria (PSB) in phosphorus (P) cycling in agricultural soils, we isolated PSB inhabiting naturally in the sandy loam soils under chickpea cropping of Patiala (Punjab State). A total of 31 bacterial isolates showing solubilizing activities were isolated on Pikovskaya agar plates. The potent phosphate solubilizers were selected for further characterization. These isolates were shown to belong to the genera Pseudomonas and Serratia by partial sequencing analysis of their respective 16S rDNA genes. ERIC-PCR based fingerprinting was done for tracking the survival of introduced populations of the PSB during mass inoculation of these strains under chickpea plots. The results showed positive correlation (r² = 0.853) among soil phosphatase activity and phosphate solubilizers population, which was also positively correlated (r² = 0.730) to available phosphorus. Identification and characterization of soil PSB for the effective plant growth-promotion broadens the spectrum of phosphate solubilizers available for field application.     

Thermotolerant phosphate solubilizing microorganisms and their interaction with mung bean

Several phosphate solubilizing microorganisms (PSM) were tested for their efficiency at 35°, 40° and 45°C. There was a marked variation in their ability to solubilise tricalcium phosphate and the effect was more pronounced at 45°C. Two bacterial and one fungal strain were found to be thermotolerant as they solubilised a large amount of tricalcium phosphate at the three tested temperatures. These thermotolerant strains were identified as Bacillus subtilis (TT₀), Bacillus circulans (TT₈) and Aspergillus niger (TT₁₀). Seed inoculation of mung bean showed a better establishment of temperature tolerant strains as revealed by the rhizosphere population. The inoculation improved nodulation, the available P₂O₅ content of the alluvial soil, root and shoot biomass, straw and grain yield and phosphorus and nitrogen uptake of the crop. Among the bacterial strains, the best effect on yield was obtained with B. subtilis. However, statistically it was equivalent to streptomycin resistant mutant (M-20) and Pseudomonas striata (27). A. niger was less effective than bacteria. Though superphosphate was found to be a better source of phosphate fertiliser, the use of rock phosphate (RP₄₀), coupled with phosphate solubilising bacteria (PSB), gave results comparable to superphosphate (SP₂₀) + PSB inoculants.     

Rhizosphere mediated nutrient management in Allium hookeri Thwaites by using phosphate solubilizing rhizobacteria and tricalcium phosphate amended soil

This work describes integrated nutrient management for cultivation of Allium hookeri by using phosphate solubilizing bacteria (PSB) applied in rhizosphere, along with tricalcium phosphate (TCP). Arthrobacter luteolus S4C7, Enterobacter asburiae S5C7, Klebsiella pneumoniae S4C9, S4C10 and S6C1, and K. quasipneumoniae S6C2, were isolated from rhizosphere of Allium hookeri Thwaites, and were found to release substantial amount of soluble phosphate (124.8–266.4?μg/mL) from TCP in vitro conditions. These isolates were experimented for plant growth promoting attributes, including IAA, siderophore, and nitrogen-fixation. Treatment with PSB resulted in enhanced growth of A. hookeri Th., which was even better with TCP amendment with PSB. K.quasipneumoniae  S6C2 resulted in 39.1% and 533.3% increase (p?≤?0.05) of root length and weight respectively. The treatment with these isolates, in TCP amended soil also resulted in 200–250% increase in available P in soil, which was maximum for K. quasipneumoniae (1.866?mg/g).     

Isolation of Phosphate Solubilizing Bacteria from Maize Rhizosphere and Their Potential for Rock Phosphate Solubilization–Mineralization and Plant Growth Promotion

Phosphate solubilizing bacteria (PSB) play a significant role in plant P nutrition by their effect on soil P dynamics and their subsequent ability to make P available to plants via solubilization and mineralization processes. This study aimed to evaluate the effect of separate and combined use of indigenous PSB, poultry manure (PM) and compost on solubilization and mineralization of rock phosphate (RP) and their subsequent effect on growth and P accumulation of maize (Zea mays L.). A group of fifty seven bacteria were isolated from the rhizosphere/rhizoplane of maize that had been grown in soils collected from varying altitudes (655–2,576 m) of the mountain region of Rawalakot, Azad Jammu and Kashmir, Pakistan. After screening, the capacity of eleven isolates to solubilize mineral phosphate was quantitatively evaluated using insoluble Ca₃(PO₄)₂ in culture medium as a time course study through spectrometer. The growth hormone producing (IAA) capacity of the isolates was also determined. Furthermore, five potential isolates were tested for their ability to increase P release capacity (mineralization) of insoluble RP in an incubation study. The effect of PSB inoculation on maize was determined in a completely randomized greenhouse experiment where root and shoot biomass and P accumulation in plants were assessed. The P solubilization index of selected isolates varied from 1.94 to 3.69, while the P solubilization efficiency ranged between 94.1% and 269.0%. The isolates MRS18 and MRS27 displayed the highest values. The P solubilization in the liquid medium was maximum at 6 and 9 days of incubation ranging between 9.91 and 44.04 µgmL^?1 and the isolates MRS27 and MRS34 exhibited the highest solubilization. Six isolates showed additional capability of producing IAA ranging between 2.66 and 28.41 µgmL^?1. Results of the incubation study indicated that P release capacity (P mineralization) of RP-amended soil varied between 6.0 and 11.8 µgPg^?1 that had been significantly increased to 30.6–36.3 µgPg^?1 (maximum value) when PSB were combined with RP. The combined application of PSB and organic amendments (PM, compost) with RP further increased P mineralization by releasing a maximum of 37.7 µgPg^?1 compared with separate application of RP (11.8 µgPg^?1) and organic amendments (21.5 and 16.5 µgPg^?1). The overall effect of PSB (as a group) with RP over RP alone on maize growth showing a relative increase in shoot length 21%, shoot fresh weight 42%, shoot dry weight 24%, root length 11%, root fresh weight 59%, root dry weight 35% and chlorophyll content 32%. This study clearly indicates that use of PSB, and organic amendments with insoluble RP could be a promising management strategy to enhance P availability in soil pool and improve plant growth in intensive cropping systems.     

In vitro evaluation of some bacterial isolates as biofertilizers and biocontrol agents against the second stage juveniles of <Emphasis Type="Italic">Meloidogyne incognita</Emphasis>

Representative soil samples were collected from soil apart and the rhizosphere of different plant varieties grown in five Egyptian Governorates. The presence of plant parasitic nematodes (PPN) and free living nematodes (FLN) in the collected samples were estimated. In addition, one hundred and 65 bacterial cultures which well known as biofertilizers (some are able to fix nitrogen and the others solubilize either phosphate or potassium) were isolated. The isolated bacteria were screened depending on their rate of growth. Thirty-five cultures of fast growing nitrogen fixing bacteria (NFB), phosphate solubilizing bacteria (PSB) and potassium solubilizing bacteria (KSB) and their cultural filtrates were tested in vitro as biocontrol agents against the second stage juvenile (J_2s) of the Meloidogyne incognita. In general, higher mortality percentages of nematodes were recorded by bacterial cultures than their comparative cultural filtrates. The highest mortality percentages were recorded by cultures of NFB7, PSB2 and KSB2 (100% at dilution 1/10), while it was 99.3, 99 and 97.8% at dilution 1/100, respectively. NFB7 exhibited a high nitrogen fixation rate (4.2 μmole N₂/mL/h), while PSB2 and KSB2 effectively solubilized phosphate and potassium comparing with the control treatments (1.94 fold of available phosphate and 2.0 fold of available potassium, respectively). NFB7, PSB2 and KSB2 isolates showed the highest protease, gelatinase and chitinase activities which were thought responsible for their nematicidal effect. The three bacterial isolates were identified as Paenibacillus polymyxa, Bacillus megaterium and Bacillus circulans, respectively.     

Cultivation-dependent characterization of rhizobacterial communities from field grown Chinese cabbage Brassica campestris ssp pekinensis and screening of traits for potential plant growth promotion

The composition of the bacterial community associated with plant roots is influenced by a variety of plant, environmental factors and also management practices. Our study aimed at detecting the root associated bacterial communities of Chinese cabbage under different fertilization regimes using cultivation dependent methods. The cultivable population was studied using plate count assay, fatty acid methyl ester (FAME) analysis and carbon substrate utilization␣(SU)using BIOLOG™ plates. Taxonomical identification of the isolates by FAME resulted in about 83% identification and they represented 9 and 14 different known bacterial genera from the rhizosphere and root interior respectively from Proteobacteria (α, β, and γ), firmicutes (actinobacteria and the Bacillus groups) and Bacteroidetes. Pseudomonas and Bacillus were associated with the plants grown under all the fertilized conditions and actinobacteria could be observed only in rhizosphere of plants grown on unfertilized plots. FAME and BIOLOG profiles of the rhizosphere and endophytic isolates could separate them with reference to fertilization. Principal component analysis (PCA) on the BIOLOG SU revealed that the isolates were metabolically dissimilar. The diversity, as revealed by the diversity indices was greater among the isolates obtained from unfertilized samples than that of fertilized ones. The isolates analyzed for different traits related to plant growth promotion revealed differences between rhizosphere and endophytic isolates and also with reference to the treatments. The highest percentage of phosphate solubilizing bacteria (PSB) and 1-aminocyclopropane-1-carboxylic acid (ACC) utilizers was recorded in chemical fertilizer treated samples, followed by the organic fertilizer treated. The results from this study indicate that fertilizers have an effect on the root associated bacterial communities of Chinese cabbage and also on their physiological characteristics related to plant growth promotion.     

Genotyping Assessment of Phosphate Solubilizing Bacteria Isolated from Rhizospheric Soil from Central Regions of Lucknow

Abstract

Phosphate solubilizing bacteria (PSB) can convert insoluble form of phosphorous (P) to an available form which is a major concern in Indian agriculture. In this study, 21 isolates having phosphate solubilizing capability were isolated from different regions of Lucknow, India. Among all, six efficient PSB were confirmed by using in vitro P estimation and 16S rRNA universal primers. The similarity detection was done using random amplified polymorphic DNA (RAPD) finger printing for genotyping the PSB isolates and to determine genetic relatedness between them. Twenty different OPA primers were tested among which four primers produced prominent, highly reproducible, and polymorphic bands. An average of 10.5 polymorphic bands per primer with the amplified DNA fragments ranging from 200 to 2000?bp in size. A dendrogram constructed from these data indicated 25–76% homology. Highest similarity was found in between Bacillus anthracis and Bacillus cereus with 33.8% similarity while least dissimilarity was found in B. anthracis and Pseudomonas fragi with 12% of similarity. These findings provide that there is a great genetic diversity between bacterial isolates from different geographical regions and RAPD can be used as a specific, time consuming and also proves as a reliable molecular tool which helps in strain level discrimination.     

一株高效解磷菌的筛选鉴定及溶磷性能

【背景】土壤中大部分磷元素是以难溶性磷酸盐的形式存在,不能被农作物有效利用,而传统化学肥料会带来环境污染等问题。【目的】解决土壤磷缺失现状,开发新型、安全、高效的微生物菌肥。【方法】取武汉科技大学图书馆后土壤为试验材料,筛选出一株高效解磷菌。通过个体形态鉴定、生理生化鉴定、16S rRNA基因序列分析鉴定菌株,以NBRIP为基础培养基进行条件优化,借助高效液相色谱进行细菌解磷机理探究。【结果】所筛选的高效解磷菌株为唐菖蒲伯克霍尔德氏菌(Burkholderia gladioli)。在20种氨基酸中,D-蛋氨酸对菌株的生长和溶磷促进作用最好,促进效果达到19.09%和16.16%,甲酸钠对菌株的生长和溶磷有抑制效果,抑制效果达到39.08%和10.66%。该菌株通过分泌葡萄糖醛酸、D-L-苹果酸等有机酸溶解环境中的磷酸盐,将菌株制作成菌肥对辣椒幼苗有明显的促生长作用。【结论】利用唐菖蒲伯克霍尔德氏菌(Burkholderia gladioli)分泌有机酸溶解土壤中的磷酸盐,可为生物肥料的制备和应用提供一定的理论参考。     

Role of halotolerant phosphate‐solubilising bacteria on growth promotion of peanut (Arachis hypogaea) under saline soil

Soil salinity is a major abiotic stress that limits plant growth, and inoculating plant growth‐promoting rhizobacteria is a well‐known strategy to reduce stressors under adverse soil conditions. This study was conducted to assess the effect of halotolerant phosphate‐solubilising bacteria (PSB) on protecting peanut against salt stress. Four candidate strains: Bacillus megaterium (YM13), Enterobacter sp. (YM14), Providencia rettgeri (TPM23) and Ensifer adhaeren (TPMX5) showed strong tolerance to NaCl and high phosphate‐solubilising ability even at a NaCl concentration of 1.4 M. In addition, all four strains demonstrated variable levels of phosphate solubilisation activity in the presence of various carbon and nitrogen sources, indicating high phosphate‐solubilising efficacy. Germination and radicle length of peanut seedlings increased with inoculation of PSB under both control and saline conditions. Statistically significant increase in the root length (range: 25.71–49%), stem length (19–48%), number of leaves (12.5–37%) and root/shoot biomass were observed. This could be attributed to plant hormones (i.e., indole acetic acid [IAA], abscisic acid [ABA] and gibberellic acid [GA3]) and successful root colonisation by bacterial inoculants. Root colonisation was positively correlated to plant growth and shown to be influenced by soil conditions. In addition, the PSB also improved the levels of available P in soil. The most pronounced beneficial effect on the growth of peanut plants and soil available P content was observed in the inoculation of the PSB isolates with Ca₃(PO₄)₂ addition. This is the first report that describes Providencia rettgeri as a plant growth‐promoting bacterium that may be utilised to alleviate the negative effects of salt stress on peanut plants. This bacterial species may thus be potentially used as a biofertilizer for sustaining the growth of peanut in salt‐stressed soil and in mitigating soil stress conditions.     

Utilization of phosphorus by pasture plants supplied with myo-inositol hexaphosphate is enhanced by the presence of soil micro-organisms

A range of pasture grass (Danthonia richardsonii and Phalaris aquatica) and legume (Medicago polymorpha, M. sativa, Trifolium repens and T. subterraneum) species showed limited capacity to obtain phosphorus (P) from inositol hexaphosphate (IHP), when grown in either sterile agar (pH 5.0 or 5.5) or sand-vermiculite media (pH 5.0). The total P content of shoots from IHP-supplied plants grown in agar was between 20% and 34% of that for seedlings supplied with an equivalent amount of P as inorganic phosphate (P_i), while in sand-vermiculite, the total P content of IHP-grown plants was between 5 and 10% of control plants. The poor ability of plants to utilize P from IHP resulted in significantly lower tissue P concentrations and, in general, reduced plant dry weight accumulation. In contrast, the P nutrition of plants supplied with IHP was significantly improved by inoculating media with either a cultured population of total soil micro-organisms or with a specific isolate of Pseudomonas sp., selected for its ability to release phosphate from IHP (strain CCAR59; Richardson and Hadobas, 1997 Can. J. Micro. 43, 509-516). In agar and sand-vermiculite media, respectively, the P content of IHP-grown plants increased with inoculation by up to 3.9- and 6.8-fold, such that the dry weight and P content of the plant material were equivalent to those observed for control plants supplied with P_i. However, the response to inoculation was dependent on the growth medium and the source of micro-organisms used. In sand-vermiculite, the cultured population of soil micro-organisms was effective when IHP was supplied at an equivalent level of P_i required for maximum plant growth. By comparison, inoculation of plants with the Pseudomonas strain was only effective at very high levels of IHP supply (×36), whereas in agar a response to inoculation occurred at all levels of IHP. The ability of pasture plants to acquire P from phytate was, therefore, influenced by the availability of IHP substrate, which was further affected by the presence of soil micro-organisms. Our results show that in addition to having an effect on the sorption characteristics of the growth media, soil micro-organisms also provided a source of phytase for the dephosphorylation of phytate for subsequent utilization of P_i by plants.     

Interactions of an acid tolerant strain of phosphate solubilizing bacteria with a few acid tolerant crops

Phosphate solubilizing bacteria (PSB) were isolated from sixty soil samples of various soil classes and cropping histories in Himalayan regions of Uttar Pradesh, India by enrichment culture techniques. Phosphate solubilization and acid tolerance of each strain was estimated. A strain (PAS-2) isolated froma pasture and waste land of pH 4.8, organic matter 2.6% available N 265kg ha^-1, available P₂O₅(Bray's II) 2.3kg ha^-1 and available K₂O 353 kg ha^-1 had the highest P-solubilization (45 µg P per mL per day) and also highest acid tolerance rating 42. The strain was identified as Bacillus sp. Seed inoculation of this bacterial strain resulted in significant increases in grain and vegetative yield of fingermillet (Elosine coracana), maize (Zea mays), amaranth (Amaranthus hypochondriacus), buckwheat (Fagopyrium esculentum), frenchbean (Phaseolus vulgaris) with or without added P sources. The significant grain yield (quintol ha^-1) with phosphate and seed inoculation ranged from 33.85 in maize, 26.33 in frenchbean, 22.41 in buckwheat, 20.71 in amaranth and 19.19 in fingermillet as compared to controls. The highest response was observed with frenchbean followed by fingermillet, buckwheat, amaranth and maize. Phosphate use efficiency was highest in frenchbean followed by maize and lowest and almost at par in buckwheat, amaranth and fingermillet. Available phosphate was also highest in frenchbean cultivated plot followed by amaranth, fingermillet, buckwheat and maize. The MPN count of phosphate solubilizing bacteria were also influenced by seed inoculation of strain PAS-2. Frenchbean exerted greaterrhizosphere effect followed by pseudocereals and cereals. Likewise, phosphate nutrition of crops were also improved through seed inoculation irrespective of added P sources. The study thus demonstrated that selection of efficient strain of PSB from acid soil and its seed inoculation in selected crop genotype is beneficial in boosting up crop yield in low productive hill soil. Seed inoculation also created greater rhizosphere effect over uninoculation which improved P-nutrition of crops and also available soil P.     

Isolation and characterization of halotolerant phosphate solubilizing bacteria naturally colonizing the peanut rhizosphere in salt-affected soil

Abstract

In search of efficient salt-tolerant phosphate solubilizing bacteria (PSB), we conducted a survey of PSB that naturally colonize the rhizosphere of peanuts in Xinjiang, China, a typical inland saline area. A total of 23 PSB were isolated, which included 12 Bacillus strains, three Acinetobacter strains, two Pseudomonas strains, two Brevibacillus, and one strain of Gordonia terrae, Chryseobacterium lathyri, Ensifer sesbaniae, and Paenibacillus illinoisensis. All PSB have high potential for dissolving calcium phosphate [Ca₃(PO₄)₂] within the range of 65–496?mg·L^?1, but relatively weak ability to dissolve AlPO₄ in amounts ranging from 0.4 to 11.4?mg·L^?1, FePO₄ ranging from 0.1 to 5.5?mg·L^?1, and lecithin ranging from 2.1 to 10.3?mg·L^?1. The maximum tolerance for pH is 10, and the maximum tolerance for Na₂CO₃ is 50?mm. Six isolates that can grow under the condition of 1.5?M NaCl (YMX5, YMX11, TPMX5, TPMX16, TPMX18, and TPMX19) were selected to determine their ability to dissolve Ca₃(PO₄)₂ and tolerate pH changes. This study characterized salt-tolerant PSB isolates that can be used as bioinoculants to protect plants against salt stress. In addition, we describe the phosphate-solubilizing ability of Gordonia terrae at high NaCl concentrations.     

Effect of a phosphate solubilizing bacteria on maize growth and root exudation over four levels of labile phosphorus

The influence of inoculation with phosphate-solubilizing bacteria (Enterobacter agglomerans) on maize growth, P uptake and root exudation was studied. Plants were grown in an axenic culture device where P was supplied as soluble phosphate at different contents (0, 5, 15 or 25 ppm) in the nutrient solution and as insoluble rock phosphate added to the culture sand. Experimental device was successfully used to obtain axenic root systems or good establishment of the inoculated strain in the rhizosphere of maize (10⁹ bact. g⁻¹ dry rhizospheric material). Plant growth was promoted by inoculation only for 5 or 15 ppm of soluble P in the nutrient medium without any significant effect on P uptake by the plant, suggesting that the quantities of P released by bacterial rhizospheric activity were very small. Amounts of organic compounds (total C and water-soluble C) exuded were relatively low (3.0 to 6.4% of the total plant biomass) and were reduced by bacterial inoculation when plant growth was largely promoted. Carbon balance modification and plant growth hormone production by the inoculated strain were suspected and discussed.     

Isolation and characterisation of phosphate solubilising microorganisms from the cold desert habitat of <Emphasis Type="Italic">Salix alba Linn.</Emphasis> in trans Himalayan region of Himachal Pradesh

Phosphate solubilising microorganisms (PSM) (bacteria and fungi) associated with Salix alba Linn. from Lahaul and Spiti valleys of Himachal Pradesh were isolated on Pikovskaya (PVK), modified Pikovskaya (MPVK) and National Botanical Research Institute agar (NBRIP) media by spread plating. The viable colony count of P-solubilising bacteria (PSB) and fungi (PSF) was higher in rhizosphere than that of non-rhizosphere. The frequency of PSM was highest on MPVK followed by NBRIP and PVK agar. The maximum proportion of PSM out of total bacterial and fungal count was found in upper Keylong while the least in Rong Tong. The PSB frequently were Gram-positive, endosporeforming, motile rods and belonged to Bacillus sp. The PSF mainly belonged to Penicillium sp., Aspergillus fumigatus, A. niger, A. spp. and non-sporulating sterile. Amongst the isolates with high efficiency for tricalcium phosphate (TCP) solubilisation, seven bacterial and seven fungal isolates dissolved higher amount of P from North Carolina rock phosphate (NCRP) than Mussoorie rock phosphate (MRP) and Udaipur rock phosphate (URP). However, the organisms solubilised higher-P in NBRIP broth than PVK broth. SBC5 (Bacillus sp.) and SBC7 (Bacillus sp.) bacterial isolates exhibited maximun P solubilisation (40 and 33 μg ml⁻¹ respectively) whereas FC28 (Penicillium sp.) isolate (52.3 μg ml⁻¹) amongst fungi while solubilising URP. The amount of P solubilised was positively correlated with the decrease in pH of medium. SBC5 (Bacillus sp.), SBC7 (Bacillus sp.) and SBC4 (Micrococcus) decreased the pH of medium from 6.8 to 6.08 while FC28 (Penicillium sp.) and FC39 (Penicillium sp.) isolates of fungi recorded maximum decrease in pH of medium from 6.8 to 5.96 in NBRIP broth.     

A study of the growth condition and solubilization of phosphate from hydroxyapatite byPantoea agglomerans

The growth conditions ofPantoea agglomerans, a phosphate solubilizing organism, were studied in our laboratory to determine the optimal conditions.Pantoea agglomerans showed the highest growth rate at 30°C, pH 7.0 and 2 vvm, after 50 h cultivation. A certain relationship between pH and phosphate concentration, was evident when the glucose concentration in the medium was changed. Increasing glucose concentration increased the pH buffer action of the broth. At glucose concentrations higher than the optimum concentration of 0.2 M, the cell growth was retarded.P. agglomerans consumed glucose as a substrate to produce organic acids which caused the pH decrease in the culture medium. The phosphate concentration in the medium was increased by the presence of the organic acids, which solubilized insoluble phosphates such as hydroxyapatite.     

Growth promotion of maize and lettuce by phosphate-solubilizing Rhizobium leguminosarum biovar. phaseoli

Rhizobium leguminosarum bv. phaseoli strains P31 and R1, Serratia sp. strain 22b, Pseudomonas sp. strain 24 and Rhizopus sp. strain 68 were examined for their plant growth-promoting potential on lettuce and forage maize. All these phosphate solubilizing microorganisms (PSM) were isolated from Québec soils. The plants were grown in field conditions in three sites having high to low amounts of available P. In site 1 (very fertile soil), strains R1 and 22b tended to increase the dry matter yield of lettuce shoots (p≤0.10). Lettuce inoculated with rhizobia R1 had a 6% higher P concentration (p≤0.10) than the uninoculated control. In site 2 (poorly fertile soil), the dry matter of lettuce shoots was significantly increased (p≤0.05) by inoculation with strain P31 and 24 plus 35 kg ha^-1 P-superphosphate, or with strain 68 plus 70 kg ha^-1 P-superphosphate. In site 3 (moderately fertile soil), the dry matter of maize shoots was significantly increased (p≤0.05) by inoculation with strain 24 plus 17.5 kg ha^-1 P-superphosphate, or with strain P31 plus 35 kg ha^-1 P-superphosphate. Inoculation with PSM did not affect lettuce P uptake in the less fertile soil in site 2. In site 3 with the moderately fertile soil, maize plants inoculated with strain R1 had 8% higher P concentration than the uninoculated control (p≤0.01), and 6% with strains P31 and 68 (p≤0.05). The results clearly demonstrate that rhizobia specifically selected for P solubilization function as plant growth promoting rhizobacteria with the nonlegumes lettuce and maize. The P solubilization effect seems to be the most important mechanism of plant growth promotion in moderately fertile and very fertile soils when P uptake was increased with rhizobia and other PSM.     

Effects of vesicular-arbuscular mycorrhiza on the size of the labile pool of soil phosphate

Summary Inoculation of lettuce, onion and clover with VA mycorrhizal fungus (Glomus mosseae) increased plant yields and phosphate uptake in three soils that had been depleted in phosphate. From two soils in which the labile pool of phosphate had been labelled with³²P, the specific activity of plant phosphate was the same whether the plants were mycorrhizal or non-mycorrhizal. In a third soil (Sonning) the specific activity was lower in lettuce and clover when the plants were mycorrhizal. When the experiment was repeated with the same soil under conditions that gave lower growth rates, the specific activity was the same in mycorrhizal and non-mycorrhizal plants. The lower specific activity in lettuce and clover in the first experiment is atributed to greater release of slowly exchanging phosphate (which is not in equilibrium with the added³²P), caused by the high uptake of phosphate by the mycorrhizal plants. When they occur, lower specific activities in mycorrhizal plants may therefore not necessarily indicate a solubilizing effect of the mycorrhiza on soil phosphate.