Bio-formulation of Halotolerant Phosphate Solubilizing Enterobacter cloacae HFZ-H4 Strain to Screen Different Carrier Materials  and their Shelf Life Study

Hafeez, Maryam; Ramteke, Pramod W.; Lawrence, Rubina; harose, Ramb; Suresh, Billore; Kumari, Supriya; Singh, Ajay; Singla, Ankit; Paul, Anupriya; Masih, Shalini; Masih, Harison

doi:10.20546/ijcmas.2018.701.285

Cited by 4 publications

(3 citation statements)

References 9 publications

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“… Formulation types References Strains used plants Effects of formulation on plants SOLIDE FORMULATION [203] Bacillus subtilis Lentil Biocontrol activity against Fusarium promoting their growth and increased the dry weight of lentil plants. [204] Trichoderma parareesei, Pseudomonas fluorescens, Bacillus subtilis Azotobacter chroococcum Tomato Biocontrol activity against Solanum esculentum Mill increase yield of tomato [205] Bacillus Subtilis Pseudomonas corrugata Increase maize growth parameters [206] Enterobacter cloacae (PSB) – Increase growth and yield crop in sodic/saline soil.sodic/saline soil. [207] Bacillus megatherium Vicia faba Enhanced plant biomass, increased the yield and accelerate the rhizosphere colonization [208] Pseudomonas fluorescens Bacillus subtilis Trichoderma viride tomato brinjal chill Biocontrol activity against Ralstonia solanacearum [209] Bacillus endophyticus Bacillus sphaericus Enterobacter aerogenes Bacillus safensis Bacillus megaterium(PSB) Wheat Increased root and shoot dry weights and lengths of wheat in field conditions LIQUIDE FORMULATION [210] Pseudomonas fluorescens – Increase crop protection and enhance production [211] Bacillus subtilis Wheat Biocontrol activity against Fusarium [212] Trichoderma spp.…”

Section: Bioformulation Of P-solubilizing Bacteria To Improve P Use E...mentioning

confidence: 99%

Phosphate bacterial solubilization: A key rhizosphere driving force enabling higher P use efficiency and crop productivity

Elhaissoufi

Ghoulam

Barakat

et al. 2022

Journal of Advanced Research

130

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Section: Bioformulation Of P-solubilizing Bacteria To Improve P Use E...mentioning

confidence: 99%

Phosphate bacterial solubilization: A key rhizosphere driving force enabling higher P use efficiency and crop productivity

Elhaissoufi

Ghoulam

Barakat

et al. 2022

Journal of Advanced Research

130

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“…With regard to fate of biofertilisers when released from capsule, the rhizobacterium is expected to colonize the root zone and allow for a more efficient water and nutrients absorption. Enterobacter cloacae, specifically, was previously reported to be halotolerant and phosphate solubilizing [55]. The cyanobacterium, when released, would also allow for bioavailability of nutrients and nitrogen fixation.…”

Section: Discussionmentioning

confidence: 99%

Salinity Stress Mitigation Using Encapsulated Biofertilizers for Sustainable Agriculture

et al. 2020

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The harmful effect of salinity stress on crops needs to be mitigated. Therefore, the application of microbial inoculum in combination with nanomaterials and methyl salicylate was investigated. Initially, different seeds were exposed to salinity levels treated with variable microbial treatments using different modes of applications. The microbial treatments included application of cyanobacterial strain Cyanothece sp. and the rhizobacterium Enterobacter cloacae, alone or in combination with one another, and a final treatment using combined microbial inoculum supplied with methyl salicylate. Later, different nanomaterials were used, namely, graphene, graphene oxide, and carbon nanotubes in combination with biofertilizers on the highest salinity level. The nanomaterial with microbial treatment and methyl salicylate were applied partly as a mixture in soil and partly as capsules. Results showed that salinity stress had a drastic inhibitory effect on growth parameters, especially at −5 MPa level. Nonetheless, the microbial treatments significantly alleviated the deleterious effect of salinity stress, especially when combined with methyl salicylate. When the nanomaterials were added to biofertilizers at highest salinity level, the inhibitory effect of salinity was mostly alleviated. Smart use of synergistic biofertilizers alongside the right nanomaterial, both encapsulated and in soil, would allow for mitigation and alleviation of inhibitory effect of salinity.

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“…Nhu and Diep (2017) studied that the bacterial isolates were tested in-vitro for plant growth promoting properties including nitrogen fixation, phosphate solubilization and IAA production together with producing siderophores, nitrogen-fixing and phosphate-solubilizing bacteria showed high degrees of similarity to those of the GenBank reference strains (between 97% and 100%), Bacillus subtilis and Acinetobacter sp. Hafeez et al, (2018) estimated that the halotolerant phosphate solubilizing Enterobacter cloacae HFZ-H4 strain to be used as biofertilizer formulation and study of their shelf life. Bio-formulations of Enterobacter cloacae HFZ-H4 strain in fly-ash, saw dust and rice husk ash were screened for the better survival as bacterial biofertilizers formulation.…”

Section: Identification Of Selected Bacteriamentioning

confidence: 99%

The Role of Salt-Tolerant Plant Growth Promoting Bacteria In Increasing The Resistance of Canola to Salt-Stress

Ibrahim

2022

Journal of Soil Sciences and Agricultural Engineering

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Salinity, a major environmental stress that inhibits agricultural productivity, has a negative impact on plant growth and development. The goal of this study was to use salt-tolerant bacteria to improve the plant's ability to resist salt-stress and to achieve high canola productivity in saline soil conditions. The rhizobacteria strains, Acinetobacter radioresistens (NBRC 102413) and Enterobacter cloacae (NBRC 102413) were evaluated for their ability to produce organic acids and phytohormones (IAA). A field experiment was conducted in the Agricultural Experimental Station in the Desert Research Center, Ras-Sudr, South Sinai Governorate, Egypt, during the winter season of 2018 / 2019. The researchers focused at how the inoculation with salt-tolerant bacteria and irrigation with three saline underground's water of (8.94, 11.12, and 12.1 dS m -1 ) affected some growth and yield parameters, as well as the nutrients content and intracellular organic osmolytes produced by canola plants grown in saline-calcareous soil. A. radioresistens and En. cloacae, were shown to be able to survive in a saline-nutrient broth medium containing up to 12 % NaCl. The highest values of plant fresh weight, dry weight, seeds yield and oil yield, nutrients content and osmo-protectant molecules (glycinebetaine and choline), as well as rhizosphere microbial counts and dehydrogenase activity, were recorded in treatment of the irrigation with low saline-underground water (8.94 dS m -1 ), while proline increased by using medium salineunderground water (11.12 dS m -1 ).

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Bio-formulation of Halotolerant Phosphate Solubilizing Enterobacter cloacae HFZ-H4 Strain to Screen Different Carrier Materials and their Shelf Life Study

Cited by 4 publications

References 9 publications

Phosphate bacterial solubilization: A key rhizosphere driving force enabling higher P use efficiency and crop productivity

Phosphate bacterial solubilization: A key rhizosphere driving force enabling higher P use efficiency and crop productivity

Salinity Stress Mitigation Using Encapsulated Biofertilizers for Sustainable Agriculture

The Role of Salt-Tolerant Plant Growth Promoting Bacteria In Increasing The Resistance of Canola to Salt-Stress

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