Diazotrophs for Lowering Nitrogen Pollution Crises: Looking Deep Into the Roots

Imran, Asma; Hakim, Sughra; Tariq, Mohsin; Nawaz, Muhammad Shoib; Laraib, Iqra; Gulzar, Umaira; Hanif, Muhammad Kashif; Siddique, Muhammad; Hayat, Mahnoor; Fraz, Ahmad; Ahmad, Muhammad Sajid Aqeel

doi:10.3389/fmicb.2021.637815

Cited by 30 publications

(15 citation statements)

References 151 publications

(149 reference statements)

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“…This process, called biological nitrogen fixation (BNF), is an ecological and low-cost alternative providing nitrogen to legume crops. BNF decreases the amounts of synthetic nitrogen fertilizers applied in agriculture, and thus limits its adverse impacts on natural ecosystems (e.g., it reduces greenhouse gas emissions and pollutions of surface and underground waters) 8 – 10 . This process yields about 122 million tons of fixed nitrogen per year into the environment, with 50–70 million tons of N 2- fixed biologically by agricultural crops 9 – 11 .…”

Section: Introductionmentioning

confidence: 99%

Genetic diversity of microsymbionts nodulating Trifolium pratense in subpolar and temperate climate regions

Kozieł

Kalita

Janczarek

2022

Sci Rep

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Rhizobia are soil-borne bacteria forming symbiotic associations with legumes and fixing atmospheric dinitrogen. The nitrogen-fixation potential depends on the type of host plants and microsymbionts as well as environmental factors that affect the distribution of rhizobia. In this study, we compared genetic diversity of bacteria isolated from root nodules of Trifolium pratense grown in two geographical regions (Tromsø, Norway and Lublin, Poland) located in distinct climatic (subpolar and temperate) zones. To characterize these isolates genetically, three PCR-based techniques (ERIC, BOX, and RFLP of the 16S-23S rRNA intergenic spacer), 16S rRNA sequencing, and multi-locus sequence analysis of chromosomal house-keeping genes (atpD, recA, rpoB, gyrB, and glnII) were done. Our results indicate that a great majority of the isolates are T. pratense microsymbionts belonging to Rhizobium leguminosarum sv. trifolii. A high diversity among these strains was detected. However, a lower diversity within the population derived from the subpolar region in comparison to that of the temperate region was found. Multi-locus sequence analysis showed that a majority of the strains formed distinct clusters characteristic for the individual climatic regions. The subpolar strains belonged to two (A and B) and the temperate strains to three R. leguminosarum genospecies (B, E, and K), respectively.

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Section: Introductionmentioning

confidence: 99%

Genetic diversity of microsymbionts nodulating Trifolium pratense in subpolar and temperate climate regions

Kozieł

Kalita

Janczarek

2022

Sci Rep

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“…Many of PGPM activate structural changes in plants that impart tolerance to heat stress, a phenomenon known as induced systemic tolerance (Yang et al, 2009 ). Apart from inducing direct stress tolerance, several plant-beneficial traits exhibited by these bacteria support plant growth in a synergistic manner under stress (Etesami and Beattie, 2017 ; Imran et al, 2021 ). They benefit plants either directly, through the phytohormones production, nutrient mobilization, and nitrogen fixation or indirectly by triggering the signaling cascades in the host plant.…”

Section: Microbe Therapy For Heat Tolerancementioning

confidence: 99%

“…Burkholderia phytofirmans strain PsJN is a well-reported PGPR that enhances heat tolerance in tomatoes, cold tolerance in grapevine, water stress tolerance in wheat, salt, and freezing tolerance in Arabidopsis . The same bacterium also has the antifungal property that protects the plant from biotic stress (Issa et al, 2018 ) revealing that a single bacterium can induce multiple benefits in same or different hosts (Imran et al, 2021 ).…”

Section: Microbe Therapy For Heat Tolerancementioning

confidence: 99%

What Did We Learn From Current Progress in Heat Stress Tolerance in Plants? Can Microbes Be a Solution?

et al. 2022

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Temperature is a significant parameter in agriculture since it controls seed germination and plant growth. Global warming has resulted in an irregular rise in temperature posing a serious threat to the agricultural production around the world. A slight increase in temperature acts as stress and exert an overall negative impact on different developmental stages including plant phenology, development, cellular activities, gene expression, anatomical features, the functional and structural orientation of leaves, twigs, roots, and shoots. These impacts ultimately decrease the biomass, affect reproductive process, decrease flowering and fruiting and significant yield losses. Plants have inherent mechanisms to cope with different stressors including heat which may vary depending upon the type of plant species, duration and degree of the heat stress. Plants initially adapt avoidance and then tolerance strategies to combat heat stress. The tolerance pathway involves ion transporter, osmoprotectants, antioxidants, heat shock protein which help the plants to survive under heat stress. To develop heat-tolerant plants using above-mentioned strategies requires a lot of time, expertise, and resources. On contrary, plant growth-promoting rhizobacteria (PGPRs) is a cost-effective, time-saving, and user-friendly approach to support and enhance agricultural production under a range of environmental conditions including stresses. PGPR produce and regulate various phytohormones, enzymes, and metabolites that help plant to maintain growth under heat stress. They form biofilm, decrease abscisic acid, stimulate root development, enhance heat shock proteins, deamination of ACC enzyme, and nutrient availability especially nitrogen and phosphorous. Despite extensive work done on plant heat stress tolerance in general, very few comprehensive reviews are available on the subject especially the role of microbes for plant heat tolerance. This article reviews the current studies on the retaliation, adaptation, and tolerance to heat stress at the cellular, organellar, and whole plant levels, explains different approaches, and sheds light on how microbes can help to induce heat stress tolerance in plants.

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“…The addition of plant growth-promoting bacteria (PGPB) to the compost makes it biologically active and effective for seed germination and plant growth, soil rehabilitation, and disease suppression ( Tahir et al, 2006 ; El-Akshar et al, 2016 ; Kaur et al, 2019 ). The phytohormone-producing PGPB mediate water and nutrient uptake due to increased root proliferation that ultimately improve plant growth and yield ( Imran et al, 2021 ). The effectiveness of bioactive compost, however, depends upon the survival and physiological efficiency of microbes ( Altaf et al, 2014 ) along with the organic contents and moisture-holding capacity of the compost ( Mahdi et al, 2010 ; Calabi–Floody et al, 2019 ).…”

Section: Introductionmentioning

confidence: 99%

Tailored Bioactive Compost from Agri-Waste Improves the Growth and Yield of Chili Pepper and Tomato

Imran

Sardar

Khaliq

et al. 2022

Front. Bioeng. Biotechnol.

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An extensive use of chemical fertilizers has posed a serious impact on food and environmental quality and sustainability. As the organic and biofertilizers can satisfactorily fulfill the crop’s nutritional requirement, the plants require less chemical fertilizer application; hence, the food is low in chemical residues and environment is less polluted. The agriculture crop residues, being a rich source of nutrients, can be used to feed the soil and crops after composting and is a practicable approach to sustainable waste management and organic agriculture instead of open-field burning of crop residues. This study demonstrates a feasible strategy to convert the wheat and rice plant residues into composted organic fertilizer and subsequent enrichment with plant-beneficial bacteria. The bioactive compost was then tested in a series of in vitro and in vivo experiments for validating its role in growing organic vegetables. The compost was enriched with a blend of micronutrients, such as zinc, magnesium, and iron, and a multi-trait bacterial consortium AAP (Azospirillum, Arthrobacter, and Pseudomonas spp.). The bacterial consortium AAP showed survival up to 180 days post-inoculation while maintaining their PGP traits. Field emission scanning electron microscopic analysis and fluorescence in situ hybridization (FISH) of bioactive compost further elaborated the morphology and confirmed the PGPR survival and distribution. Plant inoculation of this bioactive compost showed significant improvement in the growth and yield of chilies and tomato without any additional chemical fertilizer yielding a high value to cost ratio. An increase of ≈35% in chlorophyll contents, ≈25% in biomass, and ≈75% in yield was observed in chilies and tomatoes. The increase in N was 18.7 and 25%, while in P contents were 18.5 and 19% in chilies and tomatoes, respectively. The application of bioactive compost significantly stimulated the bacterial population as well as the phosphatase and dehydrogenase activities of soil. These results suggest that bioactive compost can serve as a source of bioorganic fertilizer to get maximum benefits regarding vegetable yield, soil quality, and fertilizer saving with the anticipated application for other food crops. It is a possible win-win situation for environmental sustainability and food security.

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Diazotrophs for Lowering Nitrogen Pollution Crises: Looking Deep Into the Roots

Cited by 30 publications

References 151 publications

Genetic diversity of microsymbionts nodulating Trifolium pratense in subpolar and temperate climate regions

Genetic diversity of microsymbionts nodulating Trifolium pratense in subpolar and temperate climate regions

What Did We Learn From Current Progress in Heat Stress Tolerance in Plants? Can Microbes Be a Solution?

Tailored Bioactive Compost from Agri-Waste Improves the Growth and Yield of Chili Pepper and Tomato

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