苎麻促生菌的筛选、鉴定及其促生效应

【目的】以苎麻(Boehmeria nivea L. Gaud)根及根围土壤为研究材料,进行苎麻促生菌的筛选,并初步探索其促生作用机制。【方法】首先,以溶磷和解钾为基本筛选标准,初筛菌株在实验室条件下测定多项促生能力进行复筛;然后通过种子萌发、盆栽试验测定菌株对苎麻的促生效应,最后,通过形态观察、生理生化特性和16S rRNA基因序列同源性分析,对促生菌株进行分类学鉴定。【结果】从苎麻根和根围土壤中分离得到了13株菌同时具备溶磷和解钾能力,其中4株菌(RA-2、RAM-2、RAM-5和RAM-6)具备产铁载体、产IAA和产氨能力。种子萌发和盆栽试验的测定结果显示：4株菌株均能促进苎麻种子的萌发和植株的生长,其中菌株RA-2和RAM-5相比于对照处理能显著提高苎麻种子的萌发率、幼根长、株高和根系干重。分类鉴定结果显示菌株RA-2和RAM-5均属于伯克霍德菌属(Burkholderia)。【结论】从苎麻根围筛选到具有促生能力的菌株,为进一步开发研制苎麻专型促生菌剂或专型微生物有机肥提供资源。     

Screening of plant growth promoting traits in heavy metals resistant bacteria: Prospects in phytoremediation

Phytoremediation is considered as a novel environmental friendly technology, which uses plants to remove or immobilize heavy metals. The use of metal-resistant plant growth-promoting bacteria (PGPB) constitutes an important technology for enhancing biomass production as well as tolerance of the plants to heavy metals. In this study, we isolated twenty seven (NF1-NF27) chromium resistant bacteria. The bacteria were tested for heavy metals (Cr, Zn, Cu, Ni, Pb and Co) resistance, Cr(VI) reduction and PGPB characters (phosphate solubilization, production of IAA and siderophores). The results showed that the bacterial isolates resist to heavy metals and reduce Cr(VI), with varying capabilities. 37.14% of the isolates have the capacity of solubilizing phosphate, 28.57% are able to produce siderophores and all isolates have the ability to produce IAA. Isolate NF2 that showed high heavy metal resistance and plant growth promotion characteristics was identified by 16S rDNA sequence analysis as a strain of Cellulosimicrobium sp.. Pot culture experiments conducted under greenhouse conditions showed that this strain was able to promote plant growth of alfalfa in control and in heavy metals (Cr, Zn and Cu) spiked soils and increased metal uptake by the plants. Thus, the potential of Cellulosimicrobium sp. for both bioremediation and plant growth promotion has significance in the management of environmental pollution.     

Maize development and grain quality are differentially affected by mycorrhizal fungi and a growth-promoting pseudomonad in the field

Arbuscular mycorrhizal (AM) fungi and plant growth-promoting bacteria (PGPB) can increase the growth and yield of major crops, and improve the quality of fruits and leaves. However, little is known about their impact on seed composition. Plants were inoculated with AM fungi and/or the bacterial strain Pseudomonas fluorescens Pf4 and harvested after 7 months of growth in open-field conditions. Plant growth parameters were measured (biomass, length and circumference of spikes, number of grains per cob, grain yield, and grain size) and protein, lipid, and starch content in grains were determined. Plant growth and yield were increased by inoculation with the microorganisms. Moreover, spikes and grains of inoculated plants were bigger than those produced by uninoculated plants. Regarding grain composition, the bacterial strain increased grain starch content, especially the digestible components, whereas AM fungi-enhanced protein, especially zein, content. Plant inoculation with the fluorescent pseudomonad and mycorrhizal fungi resulted in additive effects on grain composition. Overall, results showed that the bacterial strain and the AM fungi promoted maize growth cultivated in field conditions and differentially affected the grain nutritional content. Consequently, targeted plant inoculation with beneficial microorganisms can lead to commodities fulfilling consumer and industrial requirements.     

Azospirillum brasilense Sp 245 produces ABA in chemically-defined culture medium and increases ABA content in arabidopsis plants

Azospirillum sp. are plant growth promoting bacteria (PGPB) that increase grain yield in cereals and other species via growth promotion and/or stress alleviation. The PGPB beneficial effects have been partially attributed to bacterial production of plant hormones, especially growth promoters like auxins, gibberellins and cytokinins. This paper reports the characterization of the stress-like plant hormone abscisic acid (ABA) by GC-EIMS in cultures of A. brasilense Sp 245 after 120 h of incubation in chemically-defined media, and chemically-defined media with moderate stress (100 mM NaCl). Chemical characterization of ABA was done by gas chromatography-electron impact mass spectrometry (GC-EIMS) and quantification by selected ion monitoring (SIM) with a stable isotope of the hormone as internal standard in the media. A. brasilense cultures produced higher amounts of ABA per ml of culture when NaCl was incorporated in the culture medium. Inoculation of Arabidopsis thaliana with A. brasilense Sp 245 enhanced two-fold the plant’s ABA content. These results contribute to explain, at least to some extent, the beneficial effects of Azospirillum sp. previously found in inoculated plants placed under adverse environmental conditions.     

5株耐盐碱促生细菌的筛选鉴定及其对红小豆的促生作用

【背景】黑龙江省大庆市地处松嫩平原,土地盐碱化程度较重。盐碱土中含有大量的耐盐碱菌株,其中部分具有特殊的促生功能,可以作为有益促生菌促进植物生长,提高植物对盐碱的抗性。【目的】有效解决土地盐碱化问题,提高粮食作物产量。【方法】采集大庆地区的盐碱土壤为实验材料,在NaHCO_3终浓度为50 mmol/L、pH 9.0的条件下对土壤中耐盐碱细菌进行分离,用功能性培养基进行促生功能细菌菌株的筛选,并对相应促生物质产量进行测定;挑选促生功能较全、促生效果较好的细菌菌株,采用形态学观察、生理生化法以及16S rRNA基因序列分析法进行菌种鉴定,以确定菌株的分类学地位;在pH 8.5、15 mmol/L Na HCO3胁迫条件下测试施用促生菌株对红小豆种子发芽率、根长、芽长及插条生根数和根长的影响,以验证促生效果。【结果】对筛选获得的细菌菌株进行鉴定,29号细菌为卓贝尔氏菌属(Zobellella sp.),23、34、36和41号细菌属于盐单胞菌属(Halomonas sp.)。5株细菌均具有固氮、产植物激素吲哚乙酸(Indole-3-Acetic Acid,IAA)及ACC脱氨酶功能,34号和23号细菌具有最高植物激素IAA和ACC脱氨酶产量,分别达到了17.66 mg/L和0.31 U/mg。另外,23号细菌具有产铁载体能力,铁载体产量为3.19%;29和41号细菌具有溶有机磷功能,溶磷量分别为20.05 mg/L和34.61 mg/L。植物促生试验结果显示,在盐碱胁迫条件下,红小豆种子接菌后种子的发芽率和根长分别提高了41.67%和32.63%以上;红小豆插条接菌后,幼苗的根长和生根数与盐碱胁迫对照相比分别提升了129%和160%以上。【结论】这5株耐盐碱促生细菌能够缓解盐碱胁迫对红小豆生长的抑制作用,可以较好地促进其根系生长发育,可为研制耐盐碱促生菌肥提供优良菌种。     

焦化厂地肤根内解芘细菌的筛选及促生潜力

从多环芳烃耐受植物根内分离具多环芳烃降解功能的内生细菌并研究其促生特性,为内生菌协同宿主植物修复多环芳烃污染土壤提供基础.以长期受多环芳烃污染的焦化厂区生长的地肤为材料,从其根内分离出以芘和1-氨基环丙烷-1-羧酸(ACC)为唯一碳源和氮源的内生细菌8株.通过芘降解试验,筛选得到3株高效芘降解内生细菌KSE4、KSE7和KSE8,经鉴定分别为芽孢杆菌属、假单胞菌属和鞘氨醇菌属.通过液体培养试验,研究了3株菌在芘胁迫下产ACC脱氨酶的能力和对地肤种子萌发的影响.结果表明: 随着芘浓度(0~15 mg·L^-1)的升高,ACC脱氨酶活性降低,其中KSE7的效果最好,在芘浓度为15 mg·L^-1时,地肤发芽率和芽长分别比对照提高了44.8%和61.1%,在地肤-微生物修复焦化厂污染土壤的修复中具有一定的应用潜力.     

Effects of plant growth promoting bacteria and mycorrhizal on Capsicum annuum L. var. aviculare ([Dierbach] D’Arcy and Eshbaugh) germination under stressing abiotic conditions

Capsicum annuum var. aviculare to Tarahumara and Papago Indians and farmers of Sonora desert is a promising biological and commercial value as a natural resource from arid and semiarid coastal zones. Traditionally, apply synthetic fertilizers to compensate for soil nitrogen deficiency. However, indiscriminate use of these fertilizers might increase salinity. The inoculation by plant growth promoting bacteria (PGPB) and arbuscular mycorrhizal fungi (AMF) represents an alternative as potential bio fertilizer resources for salty areas. Seeds ecotypes from four areas of Sonora desert (Mazocahui, Baviacora, Arizpe, La Tortuga), in order to inoculate them with one species of PGPB and AMF. Two germination tests were carried out to study the effect of salinity, temperature regime (night/day) and inoculation with PGPB and AMF growth factors measured on germination (percentage and rate), plant height, root length, and produced biomass (fresh and dry matter). The results indicated that from four studied ecotypes, Mazocahui was the most outstanding of all, showing the highest germination under saline and non-saline conditions. However, the PGPB and AMF influenced the others variables evaluated. This study is the first step to obtain an ideal ecotype of C. a. var. aviculare, which grows in the northwest of México and promoting this type of microorganisms as an efficient and reliable biological product. Studies of the association of PGPB and AMF with the C. a. var. aviculare-Mazocahui ecotype are recommended to determine the extent to which these observations can be reproduced under field conditions.     

Isolation and characterization of plant growth promoting endophytic diazotrophic bacteria from Korean rice cultivars

We have isolated 576 endophytic bacteria from the leaves, stems, and roots of 10 rice cultivars and identified 12 of them as diazotrophic bacteria using a specific primer set of nif gene. Through 16S rDNA sequence analysis, nifH genes were confirmed in the two species of Penibacillus, three species of Microbacterium, three Bacillus species, and four species of Klebsiella. Rice seeds treated with these plant growth-promoting bacteria (PGPB) showed improved plant growth, increased height and dry weight and antagonistic effects against fungal pathogens. In addition, auxin and siderophore producing ability, and phosphate solubilizing activity were studied for the possible mechanisms of plant growth promotion. Among 12 isolates tested, 10 strains have shown higher auxin producing activity, 6 isolates were confirmed as strains with high siderophore producing activity while 4 isolates turned out to have high phosphate-solubilizing activity. These results strongly suggest that the endophytic diazotrophic bacteria characterized in this study could be successfully used to promote plant growth and inducing fungal resistance in plants.     

Are drought-resistance promoting bacteria cross-compatible with different plant models?

The association between plant and plant growth promoting bacteria (PGPB) contributes to the successful thriving of plants in extreme environments featured by water shortage. We have recently shown that, with respect to the non-cultivated desert soil, the rhizosphere of pepper plants cultivated under desert farming hosts PGPB communities that are endowed with a large portfolio of PGP traits. Pepper plants exposed to bacterial isolates from plants cultivated under desert farming exhibited a higher tolerance to water shortage, compared with untreated control. This promotion was mediated by a larger root system (up to 40%), stimulated by the bacteria, that enhanced plant ability to uptake water from dry soil. We provide initial evidence that the nature of the interaction can have a limited level of specificity and that PGPB isolates may determine resistance to water stress in plants others than the one of the original isolation. It is apparent that, in relation to plant resistance to water stress, a feature of primary evolutionary importance for all plants, a cross-compatibility between PGPB and different plant models exists at least on a short-term.     

Plant Growth-Promoting Bacteria Facilitate the Growth of Barley and Oats in Salt-Impacted Soil: Implications for Phytoremediation of Saline Soils

Plant growth-promoting bacteria (PGPB) strains that contain the enzyme 1-amino- cyclopropane-1-carboxylate (ACC) deaminase can lower stress ethylene levels and improve plant growth. In this study, ACC deaminase-producing bacteria were isolated from a salt-impacted (～50 dS/m) farm field, and their ability to promote plant growth of barley and oats in saline soil was investigated in pouch assays (1% NaCl), greenhouse trials (9.4 dS/m), and field trials (6–24 dS/m). A mix of previously isolated PGPB strains UW3 (Pseudomonas sp.) and UW4 (P. sp.) was also tested for comparison. Rhizobacterial isolate CMH3 (P. corrugata) and UW3+UW4 partially alleviated plant salt stress in growth pouch assays. In greenhouse trials, CMH3 enhanced root biomass of barley and oats by 200% and 50%, respectively. UW3+UW4, CMH3 and isolate CMH2 also enhanced barley and oat shoot growth by 100%–150%. In field tests, shoot biomass of oats tripled when treated with UW3+UW4 and doubled with CHM3 compared with that of untreated plants. PGPB treatment did not affect salt uptake on a per mass basis; higher plant biomass led to greater salt uptake, resulting in decreased soil salinity. This study demonstrates a method for improving plant growth in marginal saline soils. Associated implications for salt remediation are discussed.     

Associative bacteria influence maize (Zea mays L.) growth,physiology and root anatomy under different nitrogen levels

• Despite the great diversity of plant growth‐promoting bacteria (PGPB ) with potential to partially replace the use of N fertilisers in agriculture, few PGPB have been explored for the production of commercial inoculants, reinforcing the importance of identifying positive plant–bacteria interactions. Aiming to better understand the influence of PGPB inoculation in plant development, two PGPB species with distant phylogenetic relationship were inoculated in maize.
• Maize seeds were inoculated with Bacillus sp. or Azospirillum brasilense . After germination, the plants were subjected to two N treatments: full (N+) and limiting (N?) N supply. Then, anatomical, biometric and physiological analyses were performed.
• Both PGPB species modified the anatomical pattern of roots, as verified by the higher metaxylem vessel element (MVE ) number. Bacillus sp. also increased the MVE area in maize roots. Under N+ conditions, both PGPB decreased leaf protein content and led to development of shorter roots; however, Bacillus sp. increased root and shoot dry weight, whereas A. brasilense increased photosynthesis rate and leaf nitrate content. In plants subjected to N limitation (N?), photosynthesis rate and photosystem II efficiency increased in maize inoculated with Bacillus sp., whilst A. brasilense contained higher ammonium, amino acids and total soluble sugars in leaves, compared to the control.
• Plant developmental and metabolical patterns were switched by the inoculation, regardless of the inoculant bacterium used, producing similar as well as distinct modifications to the parameters studied. These results indicate that even non‐diazotrophic inoculant strains can improve the plant N status as result of the morpho‐anatomical and physiological modifications produced by the PGPB .

     

Effects of inoculation of plant-growth promoting bacteria on Ni uptake by Indian mustard

In this study, among a collection of Ni resistant bacterial strains isolated from serpentine soil, two plant growth promoting bacteria (PGPB), Ps29C and Bm4C were selected based on their ability to utilize ACC as the sole N source and promote seedling growth in roll towel assay. The Ni resistant PGPB, Ps29C and Bm4C were characterized as Pseudomonas sp. and Bacillus megaterium, respectively, on the basis of their 16s rDNA sequences. Assessment of the parameters of plant growth promotion revealed the intrinsic ability of the strains for the production of IAA, siderophore and solubilization of insoluble phosphate. Further, the plant growth promoting activity of Ps29C and Bm4C on the Indian mustard (Brassica juncea) were assessed with different concentrations of Ni in soil. Inoculation of Ps29C or Bm4C promoted plant growth and protected the plant from Ni toxicity. However, the maximum growth was observed in the plants inoculated with strain Bm4C. Inoculation with Ps29C or Bm4C had little influence on the accumulation of Ni in root and shoot system, but produced a much larger aboveground biomass. The present observations showed that the strains Ps29C and Bm4C protect the plants against the inhibitory effects of nickel, probably due to the production of IAA, siderophore and solubilization of phosphate. The above results provided a new insight into the phytoremediation of Ni contaminated soil.     

Mechanisms of action of plant growth promoting bacteria

The idea of eliminating the use of fertilizers which are sometimes environmentally unsafe is slowly becoming a reality because of the emergence of microorganisms that can serve the same purpose or even do better. Depletion of soil nutrients through leaching into the waterways and causing contamination are some of the negative effects of these chemical fertilizers that prompted the need for suitable alternatives. This brings us to the idea of using microbes that can be developed for use as biological fertilizers (biofertilizers). They are environmentally friendly as they are natural living organisms. They increase crop yield and production and, in addition, in developing countries, they are less expensive compared to chemical fertilizers. These biofertilizers are typically called plant growth-promoting bacteria (PGPB). In addition to PGPB, some fungi have also been demonstrated to promote plant growth. Apart from improving crop yields, some biofertilizers also control various plant pathogens. The objective of worldwide sustainable agriculture is much more likely to be achieved through the widespread use of biofertilizers rather than chemically synthesized fertilizers. However, to realize this objective it is essential that the many mechanisms employed by PGPB first be thoroughly understood thereby allowing workers to fully harness the potentials of these microbes. The present state of our knowledge regarding the fundamental mechanisms employed by PGPB is discussed herein.     

东乡野生稻内生细菌Fse32拮抗作物病害真菌及对水稻的促生活性

【背景】植物种子是植物内生菌筛选的重要原料,从中能够分离得到具有巨大应用价值的内生菌株。【目的】为发掘优良的种子内生细菌资源,对分离自东乡野生稻种子的内生细菌Fse32进行鉴定并研究其抗病原真菌和促生活性。【方法】通过形态学观察、生理生化特征和16SrRNA基因序列分析进行菌种鉴定,采用拮抗试验检测抑制病原真菌的活性,通过促生能力测定试验、水稻种子萌发及盆栽试验评价该菌株的促生效果。【结果】内生细菌Fse32鉴定为唐菖蒲伯克霍尔德氏菌,命名为Burkholderia gladioli Fse32。拮抗试验结果显示,菌株Fse32对禾谷镰孢菌(Fusarium graminearum)、水稻纹枯病菌(Rhizoctoniasolani)、核盘菌(Sclerotiniasclerotiorum)、大豆核盘菌(Sclerotinialibertiana)、尖孢镰刀菌(Fusariumoxysporum)和辣椒疫霉病菌(Phytophthoracapsici)均有较好的抑制作用,吲哚乙酸(indole-3-aceticacid,IAA)产率为17.95mg/L,能产铁载体,其A/Ar比值为0....     

Plant growth-promoting bacteria as inoculants in agricultural soils

Plant-microbe interactions in the rhizosphere are the determinants of plant health, productivity and soil fertility. Plant growth-promoting bacteria (PGPB) are bacteria that can enhance plant growth and protect plants from disease and abiotic stresses through a wide variety of mechanisms; those that establish close associations with plants, such as the endophytes, could be more successful in plant growth promotion. Several important bacterial characteristics, such as biological nitrogen fixation, phosphate solubilization, ACC deaminase activity, and production of siderophores and phytohormones, can be assessed as plant growth promotion (PGP) traits. Bacterial inoculants can contribute to increase agronomic efficiency by reducing production costs and environmental pollution, once the use of chemical fertilizers can be reduced or eliminated if the inoculants are efficient. For bacterial inoculants to obtain success in improving plant growth and productivity, several processes involved can influence the efficiency of inoculation, as for example the exudation by plant roots, the bacterial colonization in the roots, and soil health. This review presents an overview of the importance of soil-plant-microbe interactions to the development of efficient inoculants, once PGPB are extensively studied microorganisms, representing a very diverse group of easily accessible beneficial bacteria.     

紫花苜蓿根际氢氧化细菌的分离及其对小麦种子促生作用的研究

从大豆植物根际分离的氢氧化细菌对植物的生长有促进作用,但是关于其他的豆科植物根际分离的氢氧化细菌是否也有促生作用的研究甚少。从紫花苜蓿根际土壤分离氢氧化细菌,并进行其对小麦种子促生实验的研究,判断氢氧化细菌是否有促生作用,从而丰富具有促生作用的根际微生物资源。采用MSA培养基,从铜川新区紫花苜蓿根际土壤中分离得到氢氧化细菌疑似菌株,对其进行TTC法检测菌株氢化酶活性和自养能力的特性,以获得氢氧化细菌;通过小麦种子的萌发进行促生实验验证。结果表明,16株菌株处理过的小麦根长分别增加25%～128%,芽长增长27%～73%,鲜重增加48%～103%。从苜蓿根际土壤分离出的氢氧化细菌均具有较明显的促生作用。     

Screening of Chromium-Resistant Bacteria for Plant Growth-Promoting Activities

Chromium-resistant plant growth-promoting bacteria (PGPB) were isolated from the electroplating industry waste disposal site soils at Coimbatore, India, using LB medium. The strain tolerated chromium concentrations up to 500 mg Cr⁶⁺L^?1 on LB medium. The strain was identified as Pseudomonas sp. VRK3 based on its morphological, physiological, and biochemical characteristics following Bergey's manual of determinative bacteriology. Evaluation of plant growth-promoting parameters revealed the intrinsic ability of the strain for the production of indole-3-acetic acid (IAA), siderophore, and solubilization of insoluble phosphate. Pseudomonas sp. VRK3 utilized tryptophan as a precursor for the growth and production of IAA (105.77 μg mL^?1) and also exhibited the production of siderophore. The strain utilized tricalcium phosphate as the sole source of phosphate exhibiting a high rate of phosphate solubilization (0.49 μg mL^?1). Pseudomonas sp. VRK3 showed a significant extent of chromium uptake and accumulation in their cell walls. Furthermore, Pseudomonas sp. VRK3 was demonstrated to possess mobilization of chromium from the soil that would enhance chromium availability to the plant. Potential use of this Pseudomonas sp. VRK3 as PGPB needs further testing in enhancing the growth and chromium uptake by the plants in pots under nursery conditions.     

Effect of inoculation with putative plant growth-promoting rhizobacteria isolated from Pinus spp. on Pinus pinea growth, mycorrhization and rhizosphere microbial communities

Aims: In this study, 10 putative plant growth-promoting rhizobacteria (PGPR) were assayed for their ability to improve Pinus pinea growth and mycorrhization. Methods and Results: After an inoculation assay, except for two, all strains stimulated plant growth. All bacteria altered rhizosphere microbial communities as revealed by phospholipid fatty acid analysis; associating plant growth promotion with a decrease in biological diversity. Three strains were tested for their ability to enhance pine mycorrhization with wild fungi species. Only strain BB1 increased the total number of mycorrhizal root tips. Mycorrhizas present in the roots of each treatment were identified by ribosomal RNA sequencing and denaturing gradient gel electrophoresis analysis, detecting specificity between mycorrhizal species colonizing the roots and the inoculated PGPR. Conclusions: In conclusion, BB1 appears to be a good candidate to be developed into a biofertilizer directed to enhance pine growth and mycorrhization, which should result in a better establishment rate for plants used in reforestation. Significance and Impact of the Study: This study shows the potential of PGPR to improve fitness of forest tree specie. Moreover, the specificity between the bacteria inoculated and the mycorrhiza that the plant selects involve a potential biotechnological use in production of value-added fungi.     

Encapsulation of plant growth-promoting bacteria in alginate beads enriched with humic acid

The key to achieving successful, reproducible results following the introduction of beneficial microbes into soil relies on the survival rate of the inoculated bacteria in a heterogeneous soil environment and hence an improved encapsulation method was developed. Owing to the constraints associated with the inoculum formulation, in this study, encapsulation of a plant growth promoting bacteria (PGPB) isolate Bacillus subtilis CC-pg104 was attempted with alginate by enriching the bead microenvironment with humic acid. High viability of the encapsulated bacteria was observed with minimum cell loss upon storage for 5 months. Steady and constant cell release from the bead was observed for 1 week at different pH. Encapsulated cells remained active as evidenced by their ability to solubilize calcium phosphate in vitro. Successful plant growth promotion of lettuce by the encapsulated bacteria under gnotobiotic and sterile environment was also achieved. Feasibility of this improved encapsulation technique is mainly due to the dual benefits of humic acid to microbe and plant and its chemical properties allowing an easy mixing with alginate without interfering in the formation of the alginate gel beads by cross-linking with Ca2+ ions. Thus, the encapsulation method described in this study can be effectively used to protect the PGPB inoculum from adverse conditions of the soil for their successful establishment in the rhizosphere.     

Plant growth promoting potentials of Pseudomonas spp. strain OG isolated from marine water

Abstract

Bacterium Pseudomonas spp. olive green (OG) was isolated from marine water, yet, it was characterized as plant growth promoting bacterium (PGPB). Multiple plant growth promoting traits of OG isolate were determined in vitro. It was tested positive for Indole-3-acetic acid (IAA) production with 29 µg ml^?1 of IAA yield, phosphate solubilization with 34 µg ml^?1 solubilization of Tri-calcium-phosphate and it showed maximum of 32 µg ml^?1 of ammonia production. OG isolate was affirming siderophore production, hydrocyanic acid (HCN) production and catalase production. 16S rRNA gene sequence comparison was used to identify the isolate which showed its closest neighbor to be Pseudomonas fluoroscens strain BCPBMS-1. Efficacy of this PGPB was tested on the seedling growth of two test plants chickpea and green gram. Both the test plants treated with OG-based talc bioformulation showed significant growth promotion. Chickpea showed enhanced overall fresh biomass by 24%, overall dry biomass by 27% was observed after 15 days of seeded in pots. Green gram showed enhanced overall dry biomass by 28% was observed after 10 days of seeded in pots.