Harnessing PGPRs from Asparagus officinalis to Increase the Growth and Yield of Zea mays L DOI Creative Commons
René Flores Clavo,

Danny Omar Suclupe-Campos,

Luis Castillo Rivadeneira

et al.

Microbial Ecology, Journal Year: 2024, Volume and Issue: 87(1)

Published: Dec. 1, 2024

Microbial biotechnology employs techniques that rely on the natural interactions occur in ecosystems. Bacteria, including rhizobacteria, play an important role plant growth, providing crops with alternative can mitigate negative effects of abiotic stress, such as those caused by saline environments, and increase excessive use chemical fertilizers. The present study examined promoting potential bacterial isolates obtained from rhizospheric soil roots Asparagus officinalis cultivar UF-157 F2 Viru, la Libertad, Peru. This region has high salinity levels. Seventeen strains were isolated, four which are major growth-promoting traits, characterized based their morphological molecular characteristics. These salt-tolerant bacteria screened for phosphate solubilization, indole acetic acid, deaminase activity, characterization 16S rDNA sequencing. Fifteen samples soils A. plants northern coastal desert San Jose, Lambayeque, a range salt tolerances 3 to 6%. Isolates 05, 08, 09, 11 presented maximum tolerance, ammonium quantification, IAA production. identified sequencing amplified rRNA gene found be Enterobacter sp. 05 (OQ885483), 08 (OQ885484), Pseudomonas 09 (OR398704) Klebsiella (OR398705). microorganisms promoted germination Zea mays L. plants, increased rates treatments fertilizers at 100% 50%, PGPRs height length 40 days after planting. beneficial PGPR isolated environments may lead new species used overcome detrimental stress plants. biochemical response inoculation three prove these sources products develop compounds, confirming biofertilizers environments.

Language: Английский

Harnessing microbe-based soil inoculums, strigolactones, and nanotechnology for sustainable agriculture: Mechanisms, innovations, and challenges DOI
Sourav Chattaraj, Debasis Mitra, Arindam Ganguly

et al.

Pedosphere, Journal Year: 2025, Volume and Issue: unknown

Published: Jan. 1, 2025

Language: Английский

Citations

1
Synergistic effect of Zinc Solubilizing Bacteria and Consortia on the zinc marker enzymes and gaseous exchange parameters in Rice (Oryza sativa L.) for zinc biofortification DOI
Tribhuwan Singh,

Munmun Kothari,

Sudershan Mishra

et al.

Plant Physiology and Biochemistry, Journal Year: 2025, Volume and Issue: unknown, P. 109807 - 109807

Published: March 1, 2025

Language: Английский

Citations

0
Interactive effects of arbuscular mycorrhizal fungi, plant growth-promoting rhizobacteria, and compost on durum wheat resilience, productivity, and soil health in drought-stressed environment DOI
Chayma Ikan, Abdelaziz Nilahyane, Redouane Ouhaddou

et al.

Plant and Soil, Journal Year: 2025, Volume and Issue: unknown

Published: April 6, 2025

Language: Английский

Citations

0
Biofertilizers/Biostimulants' Position in Green Economy DOI
Fatima-Zahra Akensous, Nizar El Mazouni, Abdelilah Meddich

et al.

Advances in finance, accounting, and economics book series, Journal Year: 2024, Volume and Issue: unknown, P. 245 - 266

Published: Dec. 27, 2024

Climate crisis-heating temperature trends are intensifying and further estimated to exacerbate by 2100, mainly due the unprecedented upsurging rates of greenhouse gas emissions worldwide. On one hand, nations escalating efforts for global warming not outrun 1.5 ºC threshold. other ongoing precipitation fluctuations versus ever-growing population, expected clock ≈ 9 billion 2030 10 2050, raises concerns over food (in)security. Thus, there is a dire need transition toward thinking both profitability sustainability, uncompromising environmental, economic, societal fundamentals. Therefrom, implementing green economy mindset an ambitious vision that progressively being enacted. In this setting, present book chapter revolves around biofertilizers/biostimulants as potential attenuators climate crisis' footprint with tremendous prospects horticulture why they basic pillar economy.

Language: Английский

Citations

1
Harnessing PGPRs from Asparagus officinalis to Increase the Growth and Yield of Zea mays L DOI Creative Commons
René Flores Clavo,

Danny Omar Suclupe-Campos,

Luis Castillo Rivadeneira

et al.

Microbial Ecology, Journal Year: 2024, Volume and Issue: 87(1)

Published: Dec. 1, 2024

Microbial biotechnology employs techniques that rely on the natural interactions occur in ecosystems. Bacteria, including rhizobacteria, play an important role plant growth, providing crops with alternative can mitigate negative effects of abiotic stress, such as those caused by saline environments, and increase excessive use chemical fertilizers. The present study examined promoting potential bacterial isolates obtained from rhizospheric soil roots Asparagus officinalis cultivar UF-157 F2 Viru, la Libertad, Peru. This region has high salinity levels. Seventeen strains were isolated, four which are major growth-promoting traits, characterized based their morphological molecular characteristics. These salt-tolerant bacteria screened for phosphate solubilization, indole acetic acid, deaminase activity, characterization 16S rDNA sequencing. Fifteen samples soils A. plants northern coastal desert San Jose, Lambayeque, a range salt tolerances 3 to 6%. Isolates 05, 08, 09, 11 presented maximum tolerance, ammonium quantification, IAA production. identified sequencing amplified rRNA gene found be Enterobacter sp. 05 (OQ885483), 08 (OQ885484), Pseudomonas 09 (OR398704) Klebsiella (OR398705). microorganisms promoted germination Zea mays L. plants, increased rates treatments fertilizers at 100% 50%, PGPRs height length 40 days after planting. beneficial PGPR isolated environments may lead new species used overcome detrimental stress plants. biochemical response inoculation three prove these sources products develop compounds, confirming biofertilizers environments.

Language: Английский

Citations

0