Purple Nonsulfur Bacteria for Greenhouse Gas Mitigation in Rice Systems: Mechanisms and Future Perspectives

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🔬研究者:This review provides a mechanistic synthesis of PNSB's role in GHG mitigation, identifying key knowledge gaps such as in situ microbial interactions and scalability.

🏛政策担当者:This review suggests a promising biological mitigation option for rice GHG emissions, which could inform agricultural climate policies and research funding priorities.

Background Greenhouse gas (GHG) emissions from flooded rice soils, specifically methane (CH 4 ) and nitrous oxide (N 2 O), are major contributors to agricultural global warming potential. While agronomic strategies, such as water and nutrient management, are used to mitigate, they often involve trade-offs among different gases. Objective This review synthesizes effective GHG mitigation measures, including water management, rice straw management, chemical fertilizer management, rice cultivar selection, improved cultivation practices, and the role of purple nonsulfur bacteria (PNSB) as a multi-functional microbial solution for simultaneously mitigating CH 4 and N 2 O emissions in rice systems. Results This review synthesizes current knowledge on GHG emissions from flooded rice systems and evaluates the emerging role of purple nonsulfur bacteria (PNSB) as a microbial strategy for mitigation. While conventional approaches such as water and fertilizer management can reduce emissions, their effectiveness is often constrained by agronomic trade-offs and environmental variability. Recent studies suggest that PNSB may contribute to reducing CH 4 and nitrous oxide N 2 O emissions through multiple mechanisms, including modulation of carbon substrate availability, stimulation of methanotrophic activity, competition with methanogens, and enhancement of plant nutrient uptake. Discussions Compared with existing reviews, this study provides a mechanistic synthesis linking microbial metabolism with agronomic outcomes in rice systems. Evidence from laboratory and field studies indicates that PNSB inoculation can reduce CH 4 emissions while improving plant growth. However, results remain inconsistent due to differences in soil type, management practices, and microbial strains. Key knowledge gaps include limited understanding of microbial interactions in situ , scalability of inoculation strategies, and long-term field performance. Conclusion Future research should integrate advanced analytical tools, including molecular techniques and data-driven approaches, to better resolve microbial processes and optimize PNSB-based biofertilizers. Overall, PNSB represents a promising but underexplored tool for sustainable rice production and climate change mitigation.

• crossref https://doi.org/10.2174/0118743315492146260506102224first seen 2026-05-22 04:59:21 · last seen 2026-06-04 05:35:26