Your search keyword '"PGPRs"' showing total 208 results

1. Role of ACC deaminase-producing rhizobacteria in alleviation of water stress in watermelon

Author

Yavuz, Duran, Baştaş, Kubilay Kurtuluş, Seymen, Musa, Yavuz, Nurcan, Kurtar, Ertan Sait, Süheri, Sinan, Türkmen, Önder, Gür, Ayşegül, and Kıymacı, Gülbanu

Published

2023

2. Minimizing the Adverse Impacts of Soil Salinity on Maize and Tomato Growth and Productivity through the Application of Plant Growth-Promoting Rhizobacteria.

Author

Yahyaoui, Hiba, El Allaoui, Nadia, Aziz, Aziz, Hafidi, Majida, and Habbadi, Khaoula

Subjects

*SUSTAINABLE agriculture, *PLANT growth-promoting rhizobacteria, *SOIL salinity, *AGRICULTURE, *GREENHOUSE plants, *TOMATOES

Abstract

Soil salinity significantly impacts crop productivity. In response, plant growth-promoting rhizobacteria (PGPR) offer an innovative and eco-friendly solution to mitigate salinity stress. However, research on PGPR's effects on crop physiology under varying salinity levels is still emerging. This study evaluates the impact of five bacterial strains, isolated from compost, on the growth of maize (Zea mays) and tomato (Solanum lycopersicum) plants under different levels of salt stress. This study involved treating maize and tomato seeds with five bacterial strains, and then planting them in a greenhouse under varying salt stress conditions (43 mM, 86 mM, 172 mM, 207 mM NaCl) using a Randomized Complete Block Design. Results showed that bacterial inoculation improved plant growth under saline conditions. S2015-1, S2026-2, and S2027-2 (Bacillus cereus, Acinetobacter calcoaceticus, Bacillus subtilis) were particularly effective in promoting plant growth under salt stress, especially at ionic concentrations of 43 mM and 86 mM, leading to a substantial increase in fresh and dry weight, with strain S2015-1 boosting chlorophyll by 29% at 86 mM in both crops. These results highlight the potential of PGPR to enhance crop resilience and productivity under salinity stress, promoting climate-smart agricultural practices. [ABSTRACT FROM AUTHOR]

Published

2024

3. Whole-Genome Profiling of Endophytic Strain B.L.Ns.14 from Nigella sativa Reveals Potential for Agricultural Bioenhancement.

Author

Douka, Dimitra, Spantidos, Tasos-Nektarios, Tsalgatidou, Polina C., Katinakis, Panagiotis, and Venieraki, Anastasia

Subjects

BACTERIAL genomes, AGRICULTURE, BLACK cumin, VERTICILLIUM dahliae, RHIZOCTONIA solani, ENDOPHYTIC bacteria, FUSARIUM oxysporum

Abstract

Endophytic microbes in medicinal plants often possess beneficial traits for plant health. This study focuses on the bacterial endophyte strain B.L.Ns.14, isolated from Nigella sativa leaves, which demonstrated multiple plant growth-promoting properties. In vitro tests showed that B.L.Ns.14 supports plant growth, colonization, and tolerance to abiotic stress. The strain also exhibited antifungal activity against phytopathogens such as Rhizoctonia solani, Colletotrichum acutatum, Verticillium dahliae, and Fusarium oxysporum f. sp. radicis-lycopersici. Whole-genome analysis, supported by ANI and dDDH values, identified B.L.Ns.14 as Bacillus halotolerans. Genome mining revealed 128 active carbohydrate enzymes (Cazymes) related to endophytism and biocontrol functions, along with genes involved in phosphate solubilization, siderophore and IAA production, biofilm formation, and motility. Furthermore, genes for osmolyte metabolism, Na+/H+ antiporters, and stress response proteins were also identified. The genome harbors 12 secondary metabolite biosynthetic gene clusters, including those for surfactin, plipastatin mojavensin, rhizocticin A, and bacilysin, known for their antagonistic effects against fungi. Additionally, B.L.Ns.14 promoted Arabidopsis thaliana growth under both normal and saline conditions, and enhanced Solanum lycopersicum growth via seed biopriming and root irrigation. These findings suggest that Bacillus halotolerans B.L.Ns.14 holds potential as a biocontrol and plant productivity agent, warranting further field testing. [ABSTRACT FROM AUTHOR]

Published

2024

4. Defined synthetic microbial communities colonize and benefit field-grown sorghum

Author

Fonseca-García, Citlali, Pettinga, Dean, Wilson, Andrew, Elmore, Joshua R, McClure, Ryan, Atim, Jackie, Pedraza, Julie, Hutmacher, Robert, Turumtay, Halbay, Tian, Yang, Eudes, Aymerick, Scheller, Henrik V, Egbert, Robert G, and Coleman-Derr, Devin

Subjects

Microbiology, Biological Sciences, Sorghum, Rhizosphere, Microbiota, Soil Microbiology, Bacteria, Plant Roots, synthetic community, microbiome, rhizosphere, sorghum, PGPRs, Environmental Sciences, Technology, Biological sciences, Environmental sciences

Abstract

The rhizosphere constitutes a dynamic interface between plant hosts and their associated microbial communities. Despite the acknowledged potential for enhancing plant fitness by manipulating the rhizosphere, the engineering of the rhizosphere microbiome through inoculation has posed significant challenges. These challenges are thought to arise from the competitive microbial ecosystem where introduced microbes must survive, and the absence of adaptation to the specific metabolic and environmental demands of the rhizosphere. Here, we engineered a synthetic rhizosphere community (SRC1) with the anticipation that it would exhibit a selective advantage in colonizing the host Sorghum bicolor, thereby potentially fostering its growth. SRC1 was assembled from bacterial isolates identified either for their potential role in community cohesion through network analysis or for their ability to benefit from host-specific exudate compounds. The growth performance of SRC1 was assessed in vitro on solid media, in planta under gnotobiotic laboratory conditions, and in the field. Our findings reveal that SRC1 cohesion is most robust when cultivated in the presence of the plant host under laboratory conditions, with lineages being lost from the community when grown either in vitro or in a native field setting. We establish that SRC1 effectively promotes the growth of both above- and below-ground plant phenotypes in both laboratory and native field contexts. Furthermore, in laboratory conditions, these growth enhancements correlate with the transcriptional dampening of lignin biosynthesis in the host. Collectively, these results underscore the potential utility of synthetic microbial communities for modulating crop performance in controlled and native environments alike.

Published

2024

5. Minimizing the Adverse Impacts of Soil Salinity on Maize and Tomato Growth and Productivity through the Application of Plant Growth-Promoting Rhizobacteria

Author

Hiba Yahyaoui, Nadia El Allaoui, Aziz Aziz, Majida Hafidi, and Khaoula Habbadi

Subjects

climate change, soil salinity, Solanum lycopersicum L., Zea mays L., PGPRs, sustainable agriculture, Agriculture (General), S1-972

Abstract

Soil salinity significantly impacts crop productivity. In response, plant growth-promoting rhizobacteria (PGPR) offer an innovative and eco-friendly solution to mitigate salinity stress. However, research on PGPR’s effects on crop physiology under varying salinity levels is still emerging. This study evaluates the impact of five bacterial strains, isolated from compost, on the growth of maize (Zea mays) and tomato (Solanum lycopersicum) plants under different levels of salt stress. This study involved treating maize and tomato seeds with five bacterial strains, and then planting them in a greenhouse under varying salt stress conditions (43 mM, 86 mM, 172 mM, 207 mM NaCl) using a Randomized Complete Block Design. Results showed that bacterial inoculation improved plant growth under saline conditions. S2015-1, S2026-2, and S2027-2 (Bacillus cereus, Acinetobacter calcoaceticus, Bacillus subtilis) were particularly effective in promoting plant growth under salt stress, especially at ionic concentrations of 43 mM and 86 mM, leading to a substantial increase in fresh and dry weight, with strain S2015-1 boosting chlorophyll by 29% at 86 mM in both crops. These results highlight the potential of PGPR to enhance crop resilience and productivity under salinity stress, promoting climate-smart agricultural practices.

Published

2024

6. Natural solution for the remediation of multi-metal contamination: application of natural amino acids, Pseudomonas fluorescens and Micrococcus yunnanensis to increase the phytoremediation efficiency.

Author

Gol-Soltani, Mehrnoosh, Ghasemi-Fasaei, Reza, Ronaghi, Abdolmajid, Zarei, Mehdi, Zeinali, Sedigheh, and Haderlein, Stefan B.

Subjects

*PLANT growth-promoting rhizobacteria, *CHELATING agents, *PSEUDOMONAS fluorescens, *AGRICULTURAL wastes, *AMINO acids, *QUINOA, *PLANT growth

Abstract

Natural amino acids (NAA) have been rarely investigated as chelators, despite their ability to chelate heavy metals (HMs). In the present research, the effects of extracted natural amino acids, as a natural and environmentally friendly chelate agent and the inoculation of Pseudomonas fluorescens (PF) and Micrococcus yunnanensis (MY) bacteria were investigated on some responses of quinoa in a soil polluted with Pb, Ni, Cd, and Zn. Inoculation of PGPR bacteria enhanced plant growth and phytoremediation efficiency. Pb and Cd were higher in quinoa roots, while Ni and Zn were higher in the shoots. The highest efficiencies were observed with NAA treatment and simultaneous inoculation of PF and MY bacteria for Ni, Cd, Pb, and Zn. The highest values of phytoremediation efficiency and uptake efficiency of Ni, Cd, Pb, and Zn were 21.28, 19.11, 14.96 and 18.99 μg g−1, and 31.52, 60.78, 51.89, and 25.33 μg g−1, respectively. Results of present study well demonstrated NAA extracted from blood powder acted as strong chelate agent due to their diversity in size, solubilizing ability, abundant functional groups, and potential in the formation of stable complexes with Ni, Cd, Pb, and Zn, increasing metal availability in soil and improving phytoremediation efficiency in quinoa. NOVELTY STATEMENT: This study focused on an underexplored topic, the potential of natural amino acids (NAA) and plant growth-promoting rhizobacteria (PGPRs) to enhance phytoremediation efficiency of quinoa in a multi-metal contaminated soil with the waste recycling approach. Despite their chelating abilities, NAA have been rarely studied in this context. In the present study, the effects of extracted NAA, acting as environmentally friendly chelating agents, and the inoculation of Pseudomonas fluorescens (PF) and Micrococcus yunnanensis (MY) bacteria were examined on the responses of quinoa in a soil contaminated with Pb, Ni, Cd, and Zn. HIGHLIGHTS: Three agricultural wastes were used to prepare natural amino acids. Natural amino acids caused satisfactory results in remediating HMs-polluted soil and amino acid extracted from blood powder gave the best results. Phytoremediation efficiency depends strongly on the type of metal. Pseudomonas fluorescens and Micrococcus yunnanensis improved remediation performance. [ABSTRACT FROM AUTHOR]

Published

2024

7. Investigating the impact of long-term bristlegrass coverage on rhizosphere microbiota, soil metabolites, and carbon-nitrogen dynamics for pear agronomic traits in orchards.

Author

Chunhui Shi, Xiaoqing Wang, Shuang Jiang, Jianfeng Xu, and Jun Luo

Subjects

PLANT growth-promoting rhizobacteria, ORCHARD management, POLYPHENOL oxidase, PLANT communities, SOIL dynamics, MICROBIAL metabolites

Abstract

Background: Grass coverage (GC) under no-tillage systems in orchards significantly influences underground carbon (C) and nitrogen (N) sequestration, primarily through promoting mineral nutrient utilization by rhizospheric microorganisms. However, the comprehensive impact of GC on microbial communities and plant responses using soil metabolomics remains inadequately recognized. Methods: We investigated two rhizosphere types established since 2002: bristlegrass (Setaria viridis (L.) P. Beauv.) coverage (SC) and clean cultivation (CC) to assess their effects on soil parameters, enzyme activities, and key pear agronomic traits, including yield (single fruit weight (SFW)) and qualities (soluble solids content (SSC), and total soluble sugar (TSS)). We combined microbiological analysis (16S rRNA sequencing) and non-targeted metabolomics (UPLC-MS/MS and GC-MS) to explore how microbial communities influence fruit agronomic traits and soil nutrient dynamics in pear orchards under SC conditions. Results: Our findings indicate that SC significantly enhances soil organic carbon (SOC), soil organic nitrogen (SON), the C:N ratio, and available nitrogen (AN). Moreover, SC leads to pronounced increases in soil enzyme activities involved in the C cycle and storage, including soil sucrase, β-glucosidase, polyphenol oxidase and cellulase. Microbiome analysis revealed substantial differences in microbial community composition and diversity indices between SC and CC rhizosphere soils within the 0-40 cm depth. Metabolomic analysis demonstrated significant alterations in metabolite profiles across both the 0-20 cm and 20-40 cm layers under SC conditions. The identified metabolites primarily involve sugar and amino acid-related metabolic pathways, reflecting perturbations in C and N metabolism consistent with shifts in bacterial community structure. Several plant growth-promoting rhizobacteria (PGPRs) taxa (e.g., Haliangium, Bacteroides, mle1-7, Subgroup_22, Ellin6067, MND1, Flavobacterium, and Cellvibrio) were enriched under SC, associated with metabolites such as sucrose, N-acetyl-D-glucosamine, N-acetyl-L-glutamic acid, rhamnose, UDP-GlcNAc and D-maltose. These findings suggest their roles in promoting C and N sequestration processes through sucrose synthesis and glycolytic pathways in the soil, which was significantly correlated with the formation of agronomic traits such as fruit yield, SFW SSC and TSS (p<0.05), and SC treatments significantly increased yields by 35.40-62.72% and sucrose content in TSS by 2.43-3.96 times than CC treatments. Conclusion: This study provides valuable insights into the effects of SC on soil microbial communities and plant physiology, enhancing our understanding of their implications for sustainable orchard management. [ABSTRACT FROM AUTHOR]

Published

2024

8. Radiation-Tolerant Fibrivirga spp. from Rhizosphere Soil: Genome Insights and Potential in Agriculture.

Author

Srinivasan, Sathiyaraj

Subjects

*BIOTECHNOLOGY, *AGRICULTURE, *SUSTAINABLE agriculture, *PLANT biomass, *WHOLE genome sequencing

Abstract

The rhizosphere of plants contains a wide range of microorganisms that can be cultivated and used for the benefit of agricultural practices. From garden soil near the rhizosphere region, Strain ES10-3-2-2 was isolated, and the cells were Gram-negative, aerobic, non-spore-forming rods that were 0.3–0.8 µm in diameter and 1.5–2.5 µm in length. The neighbor-joining method on 16S rDNA similarity revealed that the strain exhibited the highest sequence similarities with "Fibrivirga algicola JA-25" (99.2%) and Fibrella forsythia HMF5405T (97.3%). To further explore its biotechnological potentialities, we sequenced the complete genome of this strain employing the PacBio RSII sequencing platform. The genome of Strain ES10-3-2-2 comprises a 6,408,035 bp circular chromosome with a 52.8% GC content, including 5038 protein-coding genes and 52 RNA genes. The sequencing also identified three plasmids measuring 212,574 bp, 175,683 bp, and 81,564 bp. Intriguingly, annotations derived from the NCBI-PGAP, eggnog, and KEGG databases indicated the presence of genes affiliated with radiation-resistance pathway genes and plant-growth promotor key/biofertilization-related genes regarding Fe acquisition, K and P assimilation, CO2 fixation, and Fe solubilization, with essential roles in agroecosystems, as well as genes related to siderophore regulation. Additionally, T1SS, T6SS, and T9SS secretion systems are present in this species, like plant-associated bacteria. The inoculation of Strain ES10-3-2-2 to Arabidopsis significantly increases the fresh shoot and root biomass, thereby maintaining the plant quality compared to uninoculated controls. This work represents a link between radiation tolerance and the plant-growth mechanism of Strain ES10-3-2-2 based on in vitro experiments and bioinformatic approaches. Overall, the radiation-tolerant bacteria might enable the development of microbiological preparations that are extremely effective at increasing plant biomass and soil fertility, both of which are crucial for sustainable agriculture. [ABSTRACT FROM AUTHOR]

Published

2024

9. Evaluation and identification of metabolites produced by Cytobacillus firmus in the interaction with Arabidopsis thaliana plants and their effect on Solanum lycopersicum

Author

Itzel G. Arteaga-Ríos, Karen Beatriz Méndez-Rodríguez, Raul Ocampo-Pérez, María de la Luz Guerrero-González, Raúl Rodríguez-Guerra, and Pablo Delgado-Sánchez

Subjects

Diffusible compounds, Filtered metabolites, PGPRs, Plant-bacteria interaction, Plant-filtrate interaction, VOCs, Microbiology, QR1-502, Genetics, QH426-470

Abstract

Currently, the use of bio-inputs is increasing due to the need to reduce the use of agrochemicals. However, one of the limitations is to preserve the viability of the living microorganisms, so it is important to find an alternative that allows us to obtain different metabolites to produce it. We evaluated three different interactions (contact, diffusible and volatile compounds) in vitro in Arabidopsis thaliana (At) seedlings with the strain Cytobacillus firmus M10 and its filtered secondary metabolites (M10F). The results showed that the seedlings inoculated by contact with the filtrate (AtM10F) presented increases in root length (30 %) and leaf area (33 %), as well as in the volatile interaction (At/M10F) with respect to the uninoculated treatment. For both interactions, the seedlings inoculated with the bacteria by contact (AtM10) and volatile (At/M10) obtained greater biomass (48 and 57 %). Subsequently, an evaluation at the end of the A. thaliana cycle showed that the treatments obtained by contact and distance when reinoculated with the bacteria and the filtrate (AtM10, At-M10 and AtM10F) obtained 50 % more seed yield than the control treatment, while AtM10F presented 72 %, while At/M10F presented the highest no. of siliques and seeds, which increased the yield by 65 %. In the Solanum lycopersicum (Sl) experiment, the filtrate (SlM10F) showed significant differences in seedling height, leaf length and width (23, 24 and 36 %, respectively). It also promoted an increase in fresh and dry weight, producing a greater root area and larger leaves compared to the control (Sl) and the bacteria (SlM10). We performed a qualitative characterization of the secondary metabolites present in the filtrate, where we found 2,4-DTBP, sylvopinol, isophthaladehyde, and eicosane of interest with possible growth-promoting effects on A. thaliana and tomato. We identified volatile compounds present in plant-microorganism and plant-filtrate interactions as possible precursors in the induction of plant growth, among which phenols, alcohols, aldehydes, alkanes, and alkenes stand out. Most of the analyzed compounds have not been found in the literature with reports of growth promoters, is important to mention that due to their characteristic functional groups they can derive and trigger the synthesis of new molecules with agronomic application.

Published

2025

10. Mining of rice rhizobacteria to control false smut and improve plant growth in rice (Oryza sativa L.).

Author

Pandey, Neha, Rajavat, Asha Singh, Vaishnav, Richa, Singh, Arvind Nath, Kumar, Sanjay, Mishra, Vaibhav, Kumar, Madan, and Shrivastava, Neeraj

Abstract

Oryza sativa (Rice) is one of the most cultivated staple food crops in India. The crop is affected by Rice False Smut (RFS) caused by Ustilaginoidea virens (UV), which leads to a substantial reduction in the crop yield, and the mycotoxins released pose a health risk. In the present study, bacterial strains were isolated from rhizosphere soil samples collected from the eastern regions of Uttar Pradesh, India. A total of 105 isolates were screened for their antagonistic activity against U. virens and the best four among them were selected and identified using 16S rRNA sequencing. Three isolates were identified as Bacillus subtilis, and one as Bacillus amyloliquefaciens. Additionally, plant growth promoting (PGP) traits such as siderophore production, IAA production, phosphate solubilization, HCN production etc. were assessed. To assess the biocontrol activity and PGP properties in rice a talc-based bioformulation was prepared using bacterial isolates. The control of UV infection was tested on rice variety HKR-126 involving 10 treatments with screened isolates. Enhanced germination was recorded in all bacterial treatments of UV infected seeds. Greenhouse experiments were also carried out to evaluate the biocontrol efficiency until the harvest stage, as well as plant growth in different stages. Collectively, the results suggested that biopriming with talc-based formulations consisting of B. subtilis and B. amyloliquefaciens can serve as an alternative to fungicides to control the severity of UV disease in susceptible rice varieties, along with improving overall plant growth and fitness. [ABSTRACT FROM AUTHOR]

Published

2024

11. Effect of Plant Growth-Promoting Rhizobacteria (PGPRs) on Tuber Storage of Two Potato Varieties.

Author

El Allaoui, Nadia, Douira, Allal, Benbouazza, Abdellatif, Ferrahi, Moha, Achbani, El Hassan, and Habbadi, Khaoula

Subjects

PLANT growth-promoting rhizobacteria, AUREOBASIDIUM pullulans, PLANT growth, CULTIVATED plants, POSTHARVEST diseases

Abstract

Copyright of Arab Journal of Plant Protection is the property of Arab Society for Plant Protection and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

12. The Role of Microbes in Mitigating Salinity Stress: Insights and Implications for Sustainable Agriculture

Author

Sen, Krishnendu, Mandal, Anik, Dhabal, Subhadip, Islam, Sk Saruk, Dutta, Subrata, Midya, Sujoy, Förstner, Ulrich, Series Editor, Rulkens, Wim H., Series Editor, Adhikary, Partha Pratim, editor, Shit, Pravat Kumar, editor, and Laha, Jayasree, editor

Published

2024

13. Rhizospheric Soil Bacteria as Biostimulants for Phytostabilization and Reclamation of Mine Tailings

Author

Meryeme, Bennis, Zohra, Chaddad, Mouad, Lamrabet, Soufiane, Alami, Kaoutar, Kaddouri, Omar, Bouhnik, Hanaa, Abdelmoumen, El Idrissi, Mustapha Missbah, Dheeman, Shrivardhan, editor, Islam, M. Tofazzal, editor, Egamberdieva, Dilfuza, editor, and Siddiqui, Md. Nurealam, editor

Published

2024

14. Toxicity of Rhizospheric Cadmium-Contaminated Soil and Its Remediation

Author

Uddin, Shihab, Khanom, Sumona, Islam, Md. Rafiqul, Hossain, Mahmud, and Kumar, Nitish, editor

Published

2024

15. Advance Techniques Used for Decoding the Hidden Language Used During Plant–Microbe Interaction

Author

Gupta, Garima, Singh, Durgesh, Madheshiya, Kamna, Chauhan, Updesh, Singh Chauhan, Puneet, Sharma, Anil Kumar, Series Editor, Singh Chauhan, Puneet, editor, Tewari, Shri Krishna, editor, and Misra, Sankalp, editor

Published

2024

16. Unveiling the role of PGPRs (Plant Growth-Promoting Rhizobacteria) in phytoremediation of chemical pollutants and heavy metals

Author

Deepika, Tyagi, Anshul, Haritash, Anil Kumar, Madhav, Sughosh, editor, Gupta, Gyan Prakash, editor, Yadav, Rajiv Kumar, editor, Mishra, Ritu, editor, and Hullebusch, Eric van, editor

Published

2024

17. Enhancing Growth of Roselle Plants (Hibiscus sabdariffa L.) Using a Salt- and Drought-Tolerant Rhizobacteria-Soybean Biofertilizer.

Author

Riddech, Nuntavun, Ma, Yen Nhi, and Yodpet, Butsakorn

Abstract

Salinity and drought stress pose critical challenges to crop productivity, including roselle (Hibiscus sabdariffa L.). Using waste agriculture as a natural source of fertilizer to promote the activity of beneficial soil microorganisms has the potential to help agriculture in abiotic stress-affected areas by increasing plant nutrient uptake and ecological sustainability. We investigate the ability of BioSoy+ biofertilizer, which contains salt and drought stress-tolerant plant-growth-promoting rhizobacteria (PGPR) and soybean meal, to improve roselle growth under unfavorable conditions. Rhizobacteria tolerant to salt and drought stress were isolated, and evaluated for growth-promoting traits and pathogen inhibition under stress, and their identity confirmed by 16s rRNA gene sequencing. The impact of BioSoy+ on roselle growth and soil stability index during salt and drought stress was evaluated. Salt- and drought-tolerant PGPR strains Pseudomonas nicosulfuronedens AP01 and Bacillus velezensis CC03 were identified as the major component for biofertilizers. Under 2% NaCl stress, Pseudomonas nicosulfuronedens AP01 displayed outstanding phosphate solubilization and robust Sclerotium rolfsii pathogen suppression. BioSoy+ biofertilizer application significantly enhanced roselle growth under salt and water-limited conditions. BioSoy+ treatment, for example, boosted biomass by 194.74% and 68.29% at 25% field capacity and 100 mM NaCl conditions, respectively. BioSoy+ also increased relative water content, microbial activity, proline accumulation, and chlorophyll content, indicating stress reduction and better photosynthetic efficiency. This study highlights the importance of PGPR in alleviating the negative impacts of salt and drought stress. Furthermore, it emphasizes the feasibility of soybean meal as a biofertilizer carrier, fostering sustainable agricultural practices.Highlights: Pseudomonas nicosulfuronedens AP01 and Bacillus velezensis CC03 demonstrated plant-growth-promoting abilities under salt and drought stress conditions. BioSoy+, a PGPR-soybean meal biofertilizer, improved the stability index of soil. BioSoy+ application significantly increased overall plant health of roselle under salt and water-limitation conditions. BioSoy+ treatment reduced proline accumulation and enhanced chlorophyll content in roselle leaves, indicating stress alleviation and improved photosynthetic efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

18. Seed priming with plant growth-promoting rhizobacteria and supplementation of culture medium with biochar alleviated salinity damages in Prosopis koelziana seedlings.

Author

Saadatfar, Amir, Nasibi, Fatemeh, Mousavi Shahabi, Zahra, and Ahmadi Mousavi, Effat

Subjects

*PLANT growth-promoting rhizobacteria, *BIOCHAR, *MESQUITE, *SALINITY, *DIETARY supplements

Abstract

The Prosopis koelziana genus, a member of the Fabaceae family, is crucial to the ecology and economy of arid areas. It is commonly used to restore deserts, forests, and degraded soil with low fertility and high salt concentration. However, recent studies found that the seedlings of P. koelziana are highly susceptible to salinity stress despite having a high tolerance to it. To address this issue, an experiment was conducted to determine if plant growth-promoting rhizobacteria (PGPR) pretreatment and biochar application could enhance the seedlings' tolerance to saline conditions. The research showed that salinity stress decreased seedling growth but increased proline content, soluble sugar content, and antioxidant enzyme activity. Na+ ions increased in plants under salt stress, while K+ ions decreased. The results indicated that the pretreatment of plants with biochar and bacteria increased the fresh weight of seedlings by about 23%, 58%, and 50% in 200, 400, and 600 mM NaCl, respectively, compared with non-pretreated plants. Biochar and bacteria application also increased the proline content by about 62%, 46%, 32%, and 45% in 0, 200, 400, and 600 mM NaCl. This experiment showed that bacteria and biochar pretreatment of plants reduced oxidative stress and sodium uptake (20%, 28%, and 10% decrement of root Na uptake in 200, 400, and 600 mM NaCl). Therefore, these two bio stimulators should be used together for more significant effects on the salinity mitigation of P. Koelziana seedlings and the production of resistant seedlings that have a high ability to transfer to the field. [ABSTRACT FROM AUTHOR]

Published

2024

19. Effect of plant growth promoting rhizobacteria, Bacillus cereus and Pseudomonas aeruginosa on early seedling growth and seed germination of Cinnamomum tamala

Author

Prakash, Soban, Singh, Ankit, Chandra, Harish, Yadav, Archana, Kalra, Swinder Jeet Singh, Nautiyal, A.R., and Patni, Babita

Published

2023

20. Zinc oxide nanoparticles (ZnO NPs) stabilized by phytocellulose derived biopolymer and their bipartite interaction studies with agriculturally important microbes/Raphanus sativus (L.) seeds.

Author

Kumar, Ajay, Verma, Lahur Mani, Sharma, Satyawati, and Singh, Neetu

Subjects

*RADISHES, *PLANT growth-promoting rhizobacteria, *CARBOXYMETHYLCELLULOSE, *AQUATIC weeds, *WATER hyacinth, *ROOT-mean-squares, *ZINC oxide, *BIOPOLYMERS

Abstract

Zinc oxide nanoparticles (ZnO NPs) are one of the most studied metal oxide NPs (MONPs) owing to their unique physiochemical properties. The last few years have witnessed a growing interest among researchers in adopting the green chemistry approach to fabricate MONPs. We herein report the synthesis of ZnO NPs stabilized by carboxymethyl cellulose (CMC) derived from noxious aquatic weed, i.e., Eichhornia crassipes biomass (EC-CMC). The UV–Vis spectra showed maximum absorbance at ∼380 nm, and the XRD crystallite size of EC-CMC capped ZnO NPs (c-ZnO NPs) (∼26 nm) was smaller as compared to virgin ZnO NPs (v-ZnO NPs) (∼29 nm). The value of apparent strain (εA x 10−3), root mean square strain (E RMS x 10−3), stress (MPa), and energy density (KJm−3) for c-ZnO NPs obtained from the SSP plot was ∼0.893, ∼0.173, ∼116 and ∼51.83 respectively. The study also examined the differential effects of c-ZnO NPs treatment on the growth of two plant growth-promoting rhizobacteria (PGPR), i.e., Pseudomonas fluorescens (Gram -ve), and Bacillus subtilis (Gram +ve). The findings revealed that P. fluorescens (PFL) was more susceptible to c-ZnO NPs than B. subtilis (BST). Furthermore, R. sativus seeds treated with c-ZnO NPs (10–50 ppm) exhibited notable improvements in plumule length, radicle length, vigor index, and biomass content over other treatments and control. The biopriming of R. sativus seeds with PFL and BST showed synergistic effects with 10-ppm c-ZnO NPs treatment and promoted overall seedling growth. The bacterial kinetics and seed germination studies manifest that the c-ZnO NPs at lower doses have growth-promoting effects. The combination of PFL + BST+10-ppm c-ZnO NPs showed substantial improvements in the germination indices of R. sativus. The present work has demonstrated the potential of utilizing positive bipartite interaction of PGPRs and bio-stabilized ZnO NPs to develop nanoformulations promoting plant growth management. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

21. Advancement in Plant Tissue Culture-Based Research for Sustainable Exploitation of Well-Known Medicinal Herb Bacopa Monnieri.

Author

Vinod, Abhijith, Sharma, Shivika, and Sharma, Vikas

Subjects

*PLANT cells & tissues, *BACOPA monnieri, *AYURVEDIC medicine, *METABOLITES, *HERBAL medicine

Abstract

The current review focuses on the plant Bacopa monnieri, one of prominent medical herbs in Indian ayurvedic system. The plant is well known for its cognitive and memory enhancing capabilities. The plant contains many useful alkaloids and secondary metabolites. Studies have shown that it has various promising pharmacological properties which have the potential to treat many illnesses and disorders such as asthma, bronchitis, rheumatism also in for renal disease, water retention, blood cleaning etc. This leads to the over exploitation of the plant which puts a stress on the naturally available stock of the plant, therefore, it becomes a necessity to find optimum methods for mass production of the plant and its important secondary metabolites. This review attempts to compile and to discuss the advancements in methods and techniques including type of culture vessels, plant growth regulators (PGRs), effect of stress, plant growth promoting rhizobacteria (PGPRs) interactions; for in vitro propagation of Bacopa monnieri and the enhanced production of its important bioactive (bacoside) for its sustainable exploitation. [ABSTRACT FROM AUTHOR]

Published

2023

22. From Lab to Field: Biofertilizers in the 21st Century.

Author

Ibáñez, Ana, Garrido-Chamorro, Sonia, Vasco-Cárdenas, María F., and Barreiro, Carlos

Subjects

BIOFERTILIZERS, SUSTAINABLE agriculture, TWENTY-first century, ESSENTIAL nutrients, FIELD research

Abstract

Nowadays, legal regulations and social environmental concerns are converging towards the promotion of more sustainable agriculture based on organic compounds and soil preservation. These trends are fuelling the growth of the biofertilizers, which are beneficial preparations containing microorganisms able to enhance a plant's ability to uptake essential nutrients. Their production and commercialization encompass a multitude of critical steps deeply reviewed in this manuscript through an exhaustive overview of the key stages, such as microorganism selection, new environmental sources, upscaling to field trials, encapsulation, current application systems and regulatory considerations. However, although the economical expectations are promising, several methodological, environmental, and legal concerns are undermining their advancement. The redefinition of international legal frameworks, their enhancement based on trending technologies, and the fostering of multidisciplinary collaboration across sectors are key players to promote biofertilizers as eco-friendly and cost-effective alternatives to chemical fertilizers. [ABSTRACT FROM AUTHOR]

Published

2023

23. Socio-economic and Ecological Values of Sustainable Alternatives to Pesticides

Author

Awasthi, Shivangi, Vishwakarma, Devesh, Kannaujiya, Deepa, Shikha, Ramawat, Kishan Gopal, Series Editor, Ogwu, Matthew Chidozie, editor, and Chibueze Izah, Sylvester, editor

Published

2023

24. Exploration of Plant Growth Promoting Rhizobacteria (PGPRs) for Heavy Metal Bioremediation and Environmental Sustainability: Recent Advances and Future Prospects

Author

Mondal, Sumita, Mukherjee, Samir Kumar, Hossain, Sk Tofajjen, and Shah, Maulin P., editor

Published

2023

25. Role of Plant Growth-Promoting Rhizobacteria Mitigating Drought Stress in Maize

Author

Shaffique, Shifa, Imran, Muhammad, Wani, Shabir Hussain, Pande, Anjali, Rahim, Waqas, Aaqil khan, Muhamad, Kang, Sang-Mo, Lee, In-Jung, Wani, Shabir Hussain, editor, Dar, Zahoor Ahmad, editor, and Singh, Gyanendra Pratap, editor

Published

2023

26. Seed Priming and Nano Priming Techniques as Tools to Alleviate Osmotic Stress in Legumes

Author

Mouradi, Mohammed, Farissi, Mohamed, Khadraji, Ahmed, Bouizgaren, Abdelaziz, Qaddoury, Ahmed, Ghoulam, Cherki, Choukr-Allah, Redouane, editor, and Ragab, Ragab, editor

Published

2023

27. Stenotrophomonas rhizophila a Novel Plant-Associated Bacterium With Distinguished PGPRs Properties

Author

Asmaa Elhosieny, Mona Zayed, Shawky Selim, Ayman Yassen, and Norhan Abdel Aziz

Subjects

stenotrophomonas rhizophila, isolation, pgprs, salt stress, phosphorus solubilization, Agriculture

Abstract

Stenotrophomonas sp. is a plant-associated rhizospheric bacteria. It can enhance plant productivity. It acts as a mineral dissolution and growth promoter for plants under salt-stress conditions. The selected isolates revealed the general morphological and biochemical characteristics of Stenotrophomonas sp. All the isolates exhibited the highest growth density after 15 hr. at 30oC, resistance to different levels of salinity, different pH levels, and different temperature degrees. Also, the isolates revealed their capabilities to solubilize phosphorus and potassium and to produce different phytohormones. The isolate X.M9 exhibited the highest growth performance in the form of 1.376,1.326,1.292,1.053 and 1.059 OD in most salts’ concentrations compared to all tested isolates respectively. In addition, it (X.M9) exhibited the highest resistance to low temperatures 10 and 15oC being 0.917 and 1.354 OD respectively. The isolate X.M9 recorded the highest IAA of 83.73 mg/100ml compared to all the tested isolates. The isolate X.M9 was identified using 16 SRNA sequencing and submitted to the GenBank database un-der accession number No: OP050187 as Stenotrophomonas rhizophila.

Published

2023

28. PGPR-driven phytoremediation and physiobiochemical response of Miscanthus × giganteus to stress induced by the trace elements.

Author

Nurzhanova, Asil A., Pidlisnyuk, Valentina, Berzhanova, Ramza, Nurmagambetova, Asiya S., Terletskaya, Nina, Omirbekova, Nargul, Berkinbayev, Galym, and Mamirova, Aigerim

Subjects

MISCANTHUS, PHYTOREMEDIATION, GLUTATHIONE reductase, CULTIVATED plants, PLANT cells & tissues, TRACE elements, SUPEROXIDES

Abstract

The effect of inoculation of Miscanthus × giganteus Greef et Deu by the plant growth promoting rhizobacteria (PGPRs) to the phytoremediation process and physio-biochemical plant's parameters was investigated in soil contaminated with the trace elements (TEs) from the Tekeli mining complex, Kazakhstan. Yeast Trichosporon sp. CA1, strains Rhizobium sp. Zn1-1, Shinella sp. Zn5-6, and Pseudomonas sp. CHA1-4, resistant to Zn and Pb, were isolated from the rhizosphere of M × g when the plant was cultivated in the same contaminated soil. Results illustrated that inoculation improved M × g adaptability to TEs toxicity by increasing the tolerance index to 2.9. The treatment enhanced the aboveground biomass yield by up to 163%, root biomass by up to 240%, chlorophyll content by up to 30%, and Chla/b ratio by up to 21%. Through M × g active growth and development, the peak activity of antioxidant enzymes was observed: activity of superoxide dismutase and glutathione reductase was induced, while the activity of catalase and ascorbate peroxidase was inhibited. Based on bioconcentration and translocation factors it was revealed that PGPRs selectively increased the uptake of TEs or stabilised them in the M × g rhizosphere. Inoculation with PGPRs increased the stabilization of Pb, V, Cr, Co, Ni, Cu, Cd, As, and Ba in the soil and plant tissues. Further research should focus on ex situ experiments using isolated PGPRs. [ABSTRACT FROM AUTHOR]

Published

2023

29. Bioremediation of Heavy Metals by Rhizobacteria.

Author

Riseh, Roohallah Saberi, Vazvani, Mozhgan Gholizadeh, Hajabdollahi, Najmeh, and Thakur, Vijay Kumar

Abstract

Heavy elements accumulate rapidly in the soil due to industrial activities and the industrial revolution, which significantly impact the morphology, physiology, and yield of crops. Heavy metal contamination will eventually affect the plant tolerance threshold and cause changes in the plant genome and genetic structure. Changes in the plant genome lead to changes in encoded proteins and protein sequences. Consuming these mutated products can seriously affect human and animal health. Bioremediation is a process that can be applied to reduce the adverse effects of heavy metals in the soil. In this regard, bioremediation using plant growth–promoting rhizobacteria (PGPRs) as beneficial living agents can help to neutralize the negative interaction between the plant and the heavy metals. PGPRs suppress the adverse effects of heavy metals and the negative interaction of plant-heavy elements by different mechanisms such as biological adsorption and entrapment of heavy elements in extracellular capsules, reduction of metal ion concentration, and formation of complexes with metal ions inside the cell. [ABSTRACT FROM AUTHOR]

Published

2023

30. Potential of halotolerant PGPRs in growth and yield augmentation of Triticum aestivum var. HD2687 and Zea mays var. PSCL4642 cultivars under saline conditions

Author

Arun Karnwal

Subjects

wheat, maize, abiotic stress, pgprs, salinity tolerance, Biotechnology, TP248.13-248.65

Abstract

This study aimed to culture and screen salt-tolerant Plant growth promoting rhizobacteria (PGPRs) from Bougainvillea glabra rhizosphere to improve wheat HD-2687 and maize PSCL-4642 cultivars under saline conditions up to the seedling stage. Twenty-four rhizobacterial isolates were screened for salt tolerance at different NaCl levels. Indole acetic acid (IAA) production, phosphate solubilization, and siderophore and hydrogen cyanide (HCN) production of salinity-tolerant isolates were tested. Positive salt-tolerant PGPRs were further subjected to seedling studies to examine the improvement in the development of experimental crops under 50, 100, 150, and 200 mM NaCl concentrations with/without bacterial inoculant. Of the 24 isolates, BoGl123 was the most promising PGPR, which showed the maximum phosphate solubilization, and IAA, siderophore and HCN production. It was further subjected to seedling studies. In comparison with controls, BoGl123 resulted in a higher radicle length in maize (34 mm, 87.4%) and wheat (26.8 mm, 85.8%) at the 50 mM salinity level. At the 100 mM NaCl level, the radicle length of wheat and maize seedlings was increased by 82.5% and 78.6%, respectively, compared with controls. At different NaCl concentrations, BoGl123 improved the plumule length of seedlings in both crops. The stress tolerance attributes and plant growth promotion (PGP) indicate the potential of Pseudomonas fluorescens BoGl123 to be used as a microbial inoculant in the cultivation of wheat and maize under stressful conditions.

Published

2022

31. Aluminum-Immobilizing Rhizobacteria Modulate Root Exudation and Nutrient Uptake and Increase Aluminum Tolerance of Pea Mutant E107 (brz).

Author

Belimov, Andrey A., Shaposhnikov, Alexander I., Azarova, Tatiana S., Yuzikhin, Oleg S., Sekste, Edgar A., Safronova, Vera I., and Tikhonovich, Igor A.

Subjects

NUTRIENT uptake, PLANT exudates, ALUMINUM, PLANT-microbe relationships, PLANT biomass, PLANT growth-promoting rhizobacteria, PEAS, RHIZOBACTERIA

Abstract

It is well known that plant-growth-promoting rhizobacteria (PGPRs) increase the tolerance of plants to abiotic stresses; however, the counteraction of Al toxicity has received little attention. The effects of specially selected Al-tolerant and Al-immobilizing microorganisms were investigated using pea cultivar Sparkle and its Al-sensitive mutant E107 (brz). The strain Cupriavidus sp. D39 was the most-efficient in the growth promotion of hydroponically grown peas treated with 80 µM AlCl3, increasing the plant biomass of Sparkle by 20% and of E107 (brz) by two-times. This strain immobilized Al in the nutrient solution and decreased its concentration in E107 (brz) roots. The mutant showed upregulated exudation of organic acids, amino acids, and sugars in the absence or presence of Al as compared with Sparkle, and in most cases, the Al treatment stimulated exudation. Bacteria utilized root exudates and more actively colonized the root surface of E107 (brz). The exudation of tryptophan and the production of IAA by Cupriavidus sp. D39 in the root zone of the Al-treated mutant were observed. Aluminum disturbed the concentrations of nutrients in plants, but inoculation with Cupriavidus sp. D39 partially restored such negative effects. Thus, the E107 (brz) mutant is a useful tool for studying the mechanisms of plant–microbe interactions, and PGPR plays an important role in protecting plants against Al toxicity. [ABSTRACT FROM AUTHOR]

Published

2023

32. Stenotrophomonas rhizophila a Novel Plant-Associated Bacterium With Distinguished PGPRs Properties.

Author

Elatif Elhosieny, Asmaa A., Zayed, Mona S., Selim, Shawky M., and Abdel Aziz, Norhan H.

Subjects

*STENOTROPHOMONAS maltophilia, *RHIZOSPHERE, *SALINITY, *PLANT hormones, *RNA sequencing

Abstract

Stenotrophomonas sp. is a plant-associated rhizospheric bacteria. It has the capability to enhance plant productivity. It acts as a mineral dissolution and growth promoter for plants under salt-stress conditions. The selected isolates revealed the general morphological and biochemical characteristics of Stenotrophomonas sp. All the isolates exhibited the highest growth density after 15 hr. at 30oC, resistance to different levels of salinity, different pH levels, and different temperature degrees. Also, the isolates revealed their capabilities to solubilize phosphorus and potassium and to produce different phytohormones. The isolate X.M9 exhibited the highest growth performance in the form of 1.376,1.326,1.292,1.053 and 1.059 OD in most salts’ concentrations compared to all tested isolates respectively. As well it (X.M9) exhibited the highest resistance to low temperatures 10 and 15oC being 0.917 and 1.354 OD respectively. The isolate X.M9 recorded the highest IAA of 83.73 mg/100ml compared to all the tested isolates. The isolate X.M9 were identified using 16 SRNA sequencing and submitted to the GenBank database under accession number No: OP050187 as Stenotrophomonas rhizophila. [ABSTRACT FROM AUTHOR]

Published

2023

33. Microbes-Mediated Approaches for Improving Plant Productivity and Quality

Author

Srivastava, Jyoti, Verma, Shulbhi, Srivastava, Krishna, Prasad, Ram, Series Editor, and Zhang, Shi-Hong, editor

Published

2022

34. Decoding the Enigma of Drought Stress Tolerance Mechanisms in Plants and its Application in Crop Improvement

Author

Hussan, Shamshir ul, Rather, M. Ashraf, Dar, Zahoor A., Jan, Rukhsana, Dar, Zaffar Mahdi, Wani, M. Altaf, Sheikh, Farooq A., Mahdi, S. Sheraz, Gull, Musharib, Dar, Ishan Ahmad, Mahdi, Syed Sheraz, editor, and Singh, Rajbir, editor

Published

2022

35. Microbial validation of organic preparations used in natural farming

Author

Ram, R A, Israr, Ahmad, Kumar, A, and Maurya, Shailendra

Published

2022

36. Plant Growth-Promoting Rhizobacteria (PGPR): Approaches to Alleviate Abiotic Stresses for Enhancement of Growth and Development of Medicinal Plants.

Author

Kumar, Rahul, Swapnil, Prashant, Meena, Mukesh, Selpair, Shweta, and Yadav, Bal Govind

Abstract

Plants are constantly exposed to both biotic and abiotic stresses which limit their growth and development and reduce productivity. In order to tolerate them, plants initiate a multitude of stress-specific responses which modulate different physiological, molecular and cellular mechanisms. However, many times the natural methods employed by plants for overcoming the stresses are not sufficient and require external assistance from the rhizosphere. The microbial community in the rhizosphere (known as the rhizomicrobiome) undergoes intraspecific as well as interspecific interaction and signaling. The rhizomicrobiome, as biostimulants, play a pivotal role in stimulating the growth of plants and providing resilience against abiotic stress. Such rhizobacteria which promote the development of plants and increase their yield and immunity are known as PGPR (plant growth promoting rhizobacteria). On the basis of contact, they are classified into two categories, extracellular (in soil around root, root surface and cellular space) and intracellular (nitrogen-fixing bacteria). They show their effects on plant growth directly (i.e., in absence of pathogens) or indirectly. Generally, they make their niche in concentrated form around roots, as the latter exude several nutrients, such as amino acids, lipids, proteins, etc. Rhizobacteria build a special symbiotic relationship with the plant or a section of the plant's inner tissues. There are free-living PGPRs with the potential to work as biofertilizers. Additionally, studies show that PGPRs can ameliorate the effect of abiotic stresses and help in enhanced growth and development of plants producing therapeutically important compounds. This review focuses on the various mechanisms which are employed by PGPRs to mitigate the effect of different stresses in medicinal plants and enhance tolerance against these stress conditions. [ABSTRACT FROM AUTHOR]

Published

2022

37. Use of PGPR to Optimize Soil and Crop Productivity Under Abiotic Stress

Author

Rashid, Md. Mahtab, Chaturvedi, Surabhi, Vaishnav, Anukool, Choudhary, Devendra Kumar, Sharma, Anil Kumar, Series Editor, Dubey, Suresh Kumar, editor, and Verma, Satish Kumar, editor

Published

2021

38. Rhizosphere Manipulations for Sustainable Plant Growth Promotion

Author

Pant, Pooja, Negi, Ankit, Giri, Anchal, Bhatt, Pankaj, Kumar, Rishendra, Bhatt, Pankaj, editor, Gangola, Saurabh, editor, Udayanga, Dhanushka, editor, and Kumar, Govind, editor

Published

2021

39. A Proteomics Perspective for Understanding Rhizosphere Biology at Higher Altitudes

Author

Gautam, Shiv Shanker, Suyal, Deep Chandra, Soni, Ravindra, Goel, Reeta, Sharma, Anil Kumar, Series Editor, Pudake, Ramesh Namdeo, editor, Sahu, Binod Bihari, editor, Kumari, Maya, editor, and Sharma, Anil K., editor

Published

2021

40. Importance of PGPRs in the Rhizosphere

Author

Sharma, Lalan, Shukla, S. K., Jaiswal, V. P., Gaur, A., Pathak, A. D., Sharma, K. K., Singh, S. K., Nath, Manoj, editor, Bhatt, Deepesh, editor, Bhargava, Prachi, editor, and Choudhary, D. K., editor

Published

2021

41. Pseudomonas as Plant Growth-Promoting Bacteria and Its Role in Alleviation of Abiotic Stress

Author

Yasmeen, Tahira, Aziz, Abdul, Tariq, Mohsin, Arif, Muhammad Saleem, Shahzad, Sher Muhammad, Riaz, Muhammad, Javed, Aqsa, Ali, Shafaqat, Rizwan, Muhammad, Mohamed, Heba I., editor, El-Beltagi, Hossam El-Din Saad, editor, and Abd-Elsalam, Kamel A., editor

Published

2021

42. Evaluation and identification of metabolites produced by Cytobacillus firmus in the interaction with Arabidopsis thaliana plants and their effect on Solanum lycopersicum .

Author

Arteaga-Ríos IG, Méndez-Rodríguez KB, Ocampo-Pérez R, Guerrero-González ML, Rodríguez-Guerra R, and Delgado-Sánchez P

Abstract

Currently, the use of bio-inputs is increasing due to the need to reduce the use of agrochemicals. However, one of the limitations is to preserve the viability of the living microorganisms, so it is important to find an alternative that allows us to obtain different metabolites to produce it. We evaluated three different interactions (contact, diffusible and volatile compounds) in vitro in Arabidopsis thaliana (At) seedlings with the strain Cytobacillus firmus M10 and its filtered secondary metabolites (M10F). The results showed that the seedlings inoculated by contact with the filtrate (AtM10F) presented increases in root length (30 %) and leaf area (33 %), as well as in the volatile interaction (At/M10F) with respect to the uninoculated treatment. For both interactions, the seedlings inoculated with the bacteria by contact (AtM10) and volatile (At/M10) obtained greater biomass (48 and 57 %). Subsequently, an evaluation at the end of the A. thaliana cycle showed that the treatments obtained by contact and distance when reinoculated with the bacteria and the filtrate (AtM10, At-M10 and AtM10F) obtained 50 % more seed yield than the control treatment, while AtM10F presented 72 %, while At/M10F presented the highest no. of siliques and seeds, which increased the yield by 65 %. In the Solanum lycopersicum (Sl) experiment, the filtrate (SlM10F) showed significant differences in seedling height, leaf length and width (23, 24 and 36 %, respectively). It also promoted an increase in fresh and dry weight, producing a greater root area and larger leaves compared to the control (Sl) and the bacteria (SlM10). We performed a qualitative characterization of the secondary metabolites present in the filtrate, where we found 2,4-DTBP, sylvopinol, isophthaladehyde, and eicosane of interest with possible growth-promoting effects on A. thaliana and tomato. We identified volatile compounds present in plant-microorganism and plant-filtrate interactions as possible precursors in the induction of plant growth, among which phenols, alcohols, aldehydes, alkanes, and alkenes stand out. Most of the analyzed compounds have not been found in the literature with reports of growth promoters, is important to mention that due to their characteristic functional groups they can derive and trigger the synthesis of new molecules with agronomic application., Competing Interests: The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Pablo Delgado Sanchez reports a relationship with Autonomous University of San Luis Potosi that includes: employment. If there are other authors, they declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2024 Published by Elsevier B.V.)

Published

2024

43. Potential of halotolerant PGPRs in growth and yield augmentation of Triticum aestivum var. HD2687 and Zea mays var. PSCL4642 cultivars under saline conditions.

Author

KARNWAL, ARUN

Subjects

CORN, MICROBIAL inoculants, HALOPHYTES, EXPERIMENTAL agriculture, SEEDLINGS, INDOLEACETIC acid, WHEAT

Abstract

This study aimed to culture and screen salt-tolerant Plant growth promoting rhizobacteria (PGPRs) from Bougainvillea glabra rhizosphere to improve wheat HD-2687 and maize PSCL-4642 cultivars under saline conditions up to the seedling stage. Twenty-four rhizobacterial isolates were screened for salt tolerance at different NaCl levels. Indole acetic acid (IAA) production, phosphate solubilization, and siderophore and hydrogen cyanide (HCN) production of salinity-tolerant isolates were tested. Positive salt-tolerant PGPRs were further subjected to seedling studies to examine the improvement in the development of experimental crops under 50, 100, 150, and 200 mM NaCl concentrations with/without bacterial inoculant. Of the 24 isolates, BoGl123 was the most promising PGPR, which showed the maximum phosphate solubilization, and IAA, siderophore and HCN production. It was further subjected to seedling studies. In comparison with controls, BoGl123 resulted in a higher radicle length in maize (34 mm, 87.4%) and wheat (26.8 mm, 85.8%) at the 50 mM salinity level. At the 100 mM NaCl level, the radicle length of wheat and maize seedlings was increased by 82.5% and 78.6%, respectively, compared with controls. At different NaCl concentrations, BoGl123 improved the plumule length of seedlings in both crops. The stress tolerance attributes and plant growth promotion (PGP) indicate the potential of Pseudomonas fluorescens BoGl123 to be used as a microbial inoculant in the cultivation of wheat and maize under stressful conditions. [ABSTRACT FROM AUTHOR]

Published

2022

44. Iron biofortification potential of siderophore producing rhizobacterial strains for improving growth, yield and iron contents of groundnut.

Author

Sarwar, Sair, Khaliq, Abdul, Yousra, Munazza, and Sultan, Tariq

Subjects

*BIOFORTIFICATION, *PEANUTS, *IRON, *PLANT growth, *BACILLUS subtilis, *HUMAN beings, *PLANT growth promoting substances, DEVELOPING countries

Abstract

Biofortification in crops is an effective and sustainable approach to reduce global malnutrition. Groundnut (Arachis hypogea L.) is inherently low in micronutrients, especially iron. A greenhouse study was conducted to evaluate the effect of siderophore producing bacterial strains (SPBs) on growth, yield and iron content of groundnut. Three efficient SPBs identified as Bacillus subtilis and their consortia were used alone and with soil or foliar applied iron. The results revealed that the inoculation of SPBs alone and combination with soil applied Fe, showed maximum relative increase of 63 and 86 percent in shoot fresh and dry weight respectively. Likewise, the number of pods plant−1, pod weight plant−1, 20 pod length and 100 kernel weight of groundnut were increased significantly in response to sole application SPBs and their combinations with soil applied (SA) or foliar applied (FA) iron. Moreover, nutrient (N, P, K, Zn & Fe) concentrations in kernel and straw were also showed significant differences in all treatments. Findings further revealed that the combined application of SPBs + Fe-SA increased total Fe-uptake of groundnut between 24.14 to 49.75 percent while for SPBs + Fe-FA treatment this increase varied between 14.73 to 45.72 percent (over to the SPBs alone) The overall results indicated that SPBs have the potential to increase growth, yield and nutrient contents of groundnut which advocate that microbial-mediated Fe biofortification of groundnut could be a promising strategy to ameliorate Fe deficiency-induced disordering in human beings especially in developing countries. [ABSTRACT FROM AUTHOR]

Published

2022

45. Aluminum-Immobilizing Rhizobacteria Modulate Root Exudation and Nutrient Uptake and Increase Aluminum Tolerance of Pea Mutant E107 (brz)

Author

Andrey A. Belimov, Alexander I. Shaposhnikov, Tatiana S. Azarova, Oleg S. Yuzikhin, Edgar A. Sekste, Vera I. Safronova, and Igor A. Tikhonovich

Subjects

aluminum tolerance, Cupriavidus, immobilization, pea, PGPRs, rhizosphere, Botany, QK1-989

Abstract

It is well known that plant-growth-promoting rhizobacteria (PGPRs) increase the tolerance of plants to abiotic stresses; however, the counteraction of Al toxicity has received little attention. The effects of specially selected Al-tolerant and Al-immobilizing microorganisms were investigated using pea cultivar Sparkle and its Al-sensitive mutant E107 (brz). The strain Cupriavidus sp. D39 was the most-efficient in the growth promotion of hydroponically grown peas treated with 80 µM AlCl3, increasing the plant biomass of Sparkle by 20% and of E107 (brz) by two-times. This strain immobilized Al in the nutrient solution and decreased its concentration in E107 (brz) roots. The mutant showed upregulated exudation of organic acids, amino acids, and sugars in the absence or presence of Al as compared with Sparkle, and in most cases, the Al treatment stimulated exudation. Bacteria utilized root exudates and more actively colonized the root surface of E107 (brz). The exudation of tryptophan and the production of IAA by Cupriavidus sp. D39 in the root zone of the Al-treated mutant were observed. Aluminum disturbed the concentrations of nutrients in plants, but inoculation with Cupriavidus sp. D39 partially restored such negative effects. Thus, the E107 (brz) mutant is a useful tool for studying the mechanisms of plant–microbe interactions, and PGPR plays an important role in protecting plants against Al toxicity.

Published

2023

46. A Stronger Rhizosphere Impact on the Fungal Communities Compared to the Bacterial Communities in Pecan Plantations.

Author

Liu, Junping, Tang, Yujie, Bao, Jiashu, Wang, Hankun, Peng, Fangren, Tan, Pengpeng, Chu, Guolin, and Liu, Shuai

Subjects

BACTERIAL communities, RHIZOSPHERE, FUNGAL communities, PECAN, KEYSTONE species, NUTRIENT cycles, FOREST health

Abstract

Understanding microbial communities associated with bulk and rhizosphere soils will benefit the maintenance of forest health and productivity and the sustainable development of forest ecosystems. Based on MiSeq sequencing, we explored the differences between the bulk soil and the rhizosphere soil on bacterial and fungal communities of pecan plantation. Results suggested that rhizosphere-associated fungal rather than bacterial community structures differed from bulk soil, and rhizosphere soil had lower fungal diversity than bulk soil. Actinobacteria and Cantharellales were the bacterial and fungal biomarkers of the rhizosphere soil of pecan plantation, respectively. In addition, Pleosporales , which are mainly involved in saprophylaxis and plant pathogenic processes, was identified as one of the most important fungal biomarkers for the bulk soil, and the FunGuild predicted a higher relative abundance of pathogenic fungi in bulk soil compared to rhizosphere soil. The pH, ammonium nitrogen ( NH 4 + -N), nitrate nitrogen ( NO 3 - -N), and total carbon (TC) contents drove microbial community structure and composition. The bacterial network was simpler in the rhizosphere soil than in the bulk soil. However, fungi showed the opposite network pattern. Keystone species in bacterial and fungal networks were mostly involved in nutrient cycling and the C cycling, and were found to be enriched in the rhizosphere soil. Overall, in terms of bacterial and fungal communities, the rhizosphere soil behaves more healthily than the bulk soil and has a higher potential for nutrient cycling. [ABSTRACT FROM AUTHOR]

Published

2022

47. A Stronger Rhizosphere Impact on the Fungal Communities Compared to the Bacterial Communities in Pecan Plantations

Author

Junping Liu, Yujie Tang, Jiashu Bao, Hankun Wang, Fangren Peng, Pengpeng Tan, Guolin Chu, and Shuai Liu

Subjects

rhizosphere soil, bulk soil, relevance networks, PGPRs, mycorrhizal fungi, pecan plantation, Microbiology, QR1-502

Abstract

Understanding microbial communities associated with bulk and rhizosphere soils will benefit the maintenance of forest health and productivity and the sustainable development of forest ecosystems. Based on MiSeq sequencing, we explored the differences between the bulk soil and the rhizosphere soil on bacterial and fungal communities of pecan plantation. Results suggested that rhizosphere-associated fungal rather than bacterial community structures differed from bulk soil, and rhizosphere soil had lower fungal diversity than bulk soil. Actinobacteria and Cantharellales were the bacterial and fungal biomarkers of the rhizosphere soil of pecan plantation, respectively. In addition, Pleosporales, which are mainly involved in saprophylaxis and plant pathogenic processes, was identified as one of the most important fungal biomarkers for the bulk soil, and the FunGuild predicted a higher relative abundance of pathogenic fungi in bulk soil compared to rhizosphere soil. The pH, ammonium nitrogen (NH4+-N), nitrate nitrogen (NO3--N), and total carbon (TC) contents drove microbial community structure and composition. The bacterial network was simpler in the rhizosphere soil than in the bulk soil. However, fungi showed the opposite network pattern. Keystone species in bacterial and fungal networks were mostly involved in nutrient cycling and the C cycling, and were found to be enriched in the rhizosphere soil. Overall, in terms of bacterial and fungal communities, the rhizosphere soil behaves more healthily than the bulk soil and has a higher potential for nutrient cycling.

Published

2022

48. Microbial Community and Function-Based Synthetic Bioinoculants: A Perspective for Sustainable Agriculture.

Author

Suman, Archna, Govindasamy, Venkadasamy, Ramakrishnan, Balasubramanian, Aswini, K., SaiPrasad, J., Sharma, Pushpendra, Pathak, Devashish, and Annapurna, Kannepalli

Subjects

MICROBIAL communities, HOST plants, TILLAGE, PLANT growth, MICROBIAL metabolites, URBAN agriculture, SUSTAINABLE agriculture

Abstract

Interactions among the plant microbiome and its host are dynamic, both spatially and temporally, leading to beneficial or pathogenic relationships in the rhizosphere, phyllosphere, and endosphere. These interactions range from cellular to molecular and genomic levels, exemplified by many complementing and coevolutionary relationships. The host plants acquire many metabolic and developmental traits such as alteration in their exudation pattern, acquisition of systemic tolerance, and coordination of signaling metabolites to interact with the microbial partners including bacteria, fungi, archaea, protists, and viruses. The microbiome responds by gaining or losing its traits to various molecular signals from the host plants and the environment. Such adaptive traits in the host and microbial partners make way for their coexistence, living together on, around, or inside the plants. The beneficial plant microbiome interactions have been exploited using traditional culturable approaches by isolating microbes with target functions, clearly contributing toward the host plants' growth, fitness, and stress resilience. The new knowledge gained on the unculturable members of the plant microbiome using metagenome research has clearly indicated the predominance of particular phyla/genera with presumptive functions. Practically, the culturable approach gives beneficial microbes in hand for direct use, whereas the unculturable approach gives the perfect theoretical information about the taxonomy and metabolic potential of well-colonized major microbial groups associated with the plants. To capitalize on such beneficial, endemic, and functionally diverse microbiome, the strategic approach of concomitant use of culture-dependent and culture-independent techniques would help in designing novel "biologicals" for various crops. The designed biologicals (or bioinoculants) should ensure the community's persistence due to their genomic and functional abilities. Here, we discuss the current paradigm on plant-microbiome-induced adaptive functions for the host and the strategies for synthesizing novel bioinoculants based on functions or phylum predominance of microbial communities using culturable and unculturable approaches. The effective crop-specific inclusive microbial community bioinoculants may lead to reduction in the cost of cultivation and improvement in soil and plant health for sustainable agriculture. [ABSTRACT FROM AUTHOR]

Published

2022

49. Characterization of root-endophytic actinobacteria from cactus (Opuntia ficus-indica) for plant growth promoting traits.

Author

Govindasamy, Venkadasamy, George, Priya, Ramesh, S. V., Sureshkumar, P., Rane, Jagadish, and Minhas, P. S.

Abstract

The present study is the first report of isolation and characterization of endophytic actinobacteria from cactus (Opuntia ficus-indica). A total of 179 morphologically distinct endophytic actinobacterial isolates were purified from the roots of two different genetic accessions of cactus. All these isolates were screened for their plant growth promotion traits, namely, growth on N-free medium, P-solubilization, siderophore production, ACC deaminase activity and auxin production. A majority of the endophytic actinobacterial isolates (85%) exhibited their potential for plant growth promotion under in vitro conditions. Ten among the isolates were selected based on their multi-PGP traits and were identified as Streptomyces sp. following the 16S rRNA gene sequencing and phylogenetic analysis. Plant growth promotion potential of these selected endophytic Streptomyces was studied in wheat seedlings. All these selected isolates significantly enhanced the growth parameters such as seedling length and rootlets number compared to the uninoculated control. The wheat seeds inoculated with Streptomyces tuirus VL-70-IX exhibited maximum number of rootlets (6.33) compared to uninoculated control (3.67). The inoculation of endophytic actinobacteria Streptomyces levis VL-70-XII caused maximum seedling length (20.53 cm) and root length (8.26 cm), while the inoculation of S. radiopugnans HV-VIII resulted in highest shoot length (12.33 cm). These endophytic actinobacteria isolated from the roots of cactus accessions showed potential PGP traits. This work lays foundation for characterization and selection of endophytic actinobacteria from the under-exploited, drought tolerant species such as cactus with potential cross-compatibility for the improvement of plant growth of field crops especially under abiotic stress conditions. [ABSTRACT FROM AUTHOR]

Published

2022

50. Plant growth promoting bacteria (PGPR) induce antioxidant tolerance against salinity stress through biochemical and physiological mechanisms.

Author

Neshat, Mohammadreza, Abbasi, Alireza, Hosseinzadeh, Abdulhadi, Sarikhani, Mohammad Reza, Dadashi Chavan, Davood, and Rasoulnia, Abdolrahman

Abstract

Salinity is one of the most severe abiotic stress in the world. Also, the irrigated lands have been treated with second salinity. Canola is one of the most important industrial crops for oil production all over the world which is affected by salinity. Salt stress causes imbalanced ion hemostasis (Na+ and K+) and interrupted mineral absorption in canola. Also, salinity stress leads to oxidative stress (production and accumulation of reactive oxygen species (ROS). Accumulation of ROS is extremely dangerous and lethal for plants. As a consequence, canola production is reduced under salinity stress. So, a suitable approach should be found to deal with salinity stress and prevent the loss of production oilseed. Plant growth-promoting rhizobacteria (PGPR) can colonize on the plant root surface and alleviate the salt stress effect by providing minerals like nitrogen, phosphate, and potassium. Also, they alleviate salt stress by phytohormones like auxin (IAA), cytokinin (CK), and abscisic acid (ABA). This study focus on physiological parameters like leaf area (LA), root length (RL), shoot length (SL), chlorophyll fluorescence indexes (Fv/Fm and Fv/F0), relative water content (RWC), electrolyte leakage index (ELI), photosynthesis pigments (chlorophyll a, b, and carotenoids), Na+, and K+; and biochemical parameters like malondialdehyde (MDA) content, hydrogen peroxide content (H2O2), total protein content, proline, antioxidant capacity, and antioxidant enzyme activities in canola through the inoculation with Enterobacter sp. S16-3 and Pseudomonas sp. C16-2O. This study showed that LA, RL, SL, chlorophyll fluorescence indexes, RWC were significantly increased and ELI was significantly decreased in bacteria inoculated treatments. Also, MDA, H2O2 were decreased, and antioxidant capacity, proline, and antioxidant enzymes were increased due to inoculation with these bacteria. Besides, the amount of K+ as an index of salinity tolerance significantly increased, and leaf Na+ content was significantly decreased. [ABSTRACT FROM AUTHOR]

Published

2022