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Cyanobacteria’s power trio: auxin, siderophores, and nitrogen fixation to foster thriving agriculture

Cyanobacteria, often overlooked in traditional agriculture, are gaining recognition for their roles in enhancing plant growth and soil health through diverse mechanisms. This review examines their multifaceted contributions to agricultural systems, highlighting their proficiency in auxin production,...

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Published in:	World journal of microbiology & biotechnology 2024-12, Vol.40 (12), p.381, Article 381
Main Authors:	Lorenzi, Adriana Sturion, Chia, Mathias Ahii
Format:	Article
Language:	English
Subjects:	Agricultural wastes Agriculture Agriculture - methods Agrochemicals Algae Applied Microbiology Auxins Biochemistry Biofertilizers Biomedical and Life Sciences Biotechnology Competitiveness Crop yield Crops, Agricultural - growth & development Crops, Agricultural - metabolism Crops, Agricultural - microbiology Cyanobacteria Cyanobacteria - growth & development Cyanobacteria - metabolism Environmental Engineering/Biotechnology Farming systems Fertilizers Indoleacetic Acids - metabolism Iron - metabolism Iron deficiency Life Sciences Meta-analysis Microbiology Nitrogen Nitrogen - metabolism Nitrogen Fixation Nitrogenation Nutrient deficiency Plant Development Plant growth Plant layout Production costs Review Seaweeds Siderophores Siderophores - metabolism Traditional farming Wastewater treatment
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creator	Lorenzi, Adriana Sturion Chia, Mathias Ahii
description	Cyanobacteria, often overlooked in traditional agriculture, are gaining recognition for their roles in enhancing plant growth and soil health through diverse mechanisms. This review examines their multifaceted contributions to agricultural systems, highlighting their proficiency in auxin production, which promotes plant growth and development. Additionally, we examined cyanobacteria’s ability to produce siderophores that enhance iron absorption and address micronutrient deficiencies, as well as their capacity for nitrogen fixation, which converts atmospheric nitrogen into a form that plants can utilize, all with the goal of reducing reliance on synthetic fertilizers. A meta-analysis of existing studies indicates significant positive effects of cyanobacteria on crop yield, although variability exists. While some research shows considerable yield increases, other studies report non-significant changes, suggesting benefits may depend on specific conditions and crop types. The overall random-effects model estimate indicates a significant aggregate effect, with a few exceptions, emphasizing the need for further research to optimize the use of cyanobacteria as biofertilizers. Although cyanobacteria-based products are limited in comparison to seaweed-derived alternatives, for instance, ongoing challenges include regulatory issues and production costs. Integrating cultivation with wastewater treatment could enhance competitiveness and viability in the agricultural market.
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subjects	Agricultural wastes Agriculture Agriculture - methods Agrochemicals Algae Applied Microbiology Auxins Biochemistry Biofertilizers Biomedical and Life Sciences Biotechnology Competitiveness Crop yield Crops, Agricultural - growth & development Crops, Agricultural - metabolism Crops, Agricultural - microbiology Cyanobacteria Cyanobacteria - growth & development Cyanobacteria - metabolism Environmental Engineering/Biotechnology Farming systems Fertilizers Indoleacetic Acids - metabolism Iron - metabolism Iron deficiency Life Sciences Meta-analysis Microbiology Nitrogen Nitrogen - metabolism Nitrogen Fixation Nitrogenation Nutrient deficiency Plant Development Plant growth Plant layout Production costs Review Seaweeds Siderophores Siderophores - metabolism Traditional farming Wastewater treatment
title	Cyanobacteria’s power trio: auxin, siderophores, and nitrogen fixation to foster thriving agriculture
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