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Engineered Bacterium Could Fertilize Crops and Reduce Pollution
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Engineered Bacterium Could Fertilize Crops and Reduce Pollution

Engineered Bacterium Could Fertilize Crops and Reduce Pollution
News

Engineered Bacterium Could Fertilize Crops and Reduce Pollution

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Researchers from Washington State University have engineered strains of the ubiquitous, nitrogen-fixing soil bacterium Azotobacter vinelandii to produce ammonia and excrete it at high concentrations, transferring it into crop plants in lieu of conventional chemical fertilizers.   


“We presented conclusive evidence that ammonia released is transferred to the rice plants,” said Florence Mus, Ph.D., assistant research professor, Institute of Biological Chemistry, Washington State University. “Our unique approach aims to provide new solutions to the challenge of replacing industrial fertilizers with custom-made bacteria.”   


In other words, this approach could mitigate a major source of environmental pollution. The research is published in Applied and Environmental Microbiology, a journal of the American Society for Microbiology.   


The investigators used gene editing techniques to engineer A.vinlandii to produce ammonia at a constant level, regardless of environmental conditions surrounding the bacteria, and to excrete it at concentrations high enough to effectively fertilize crops.   


The use of gene editing techniques in lieu of inserting transgenes into the A.vinlandii genome allowed regulatory requirements to be avoided that would have made the development process slower, and more difficult and expensive.   


The scientific motivation for the research was an interest in better understanding nitrogen fixation—that is, the chemical processes by which atmospheric nitrogen is assimilated into organic compounds as part of the nitrogen cycle. “Our work helps provide a more complete, fundamental understanding of the factors that underpin gene expression in a model nitrogen fixing microorganism and defines the biochemistry that brings about ammonia excretion in A.vinelandii,” said Mus. 


The practical motivation for the research was to reduce the major water pollution problems that arise when excess nitrogen fertilizer gets washed into waterways. This causes algal blooms that deplete oxygen and kill off fish and other aquatic life, creating “dead zones” in lakes, rivers and expanses of ocean. The dead zone in the northern Gulf of Mexico encompasses nearly 6,400 square miles.   


To this end, the investigators are designing the bacteria to produce ammonia at a steady rate. But they expect to be able to design different groups of A.vinlandii to produce ammonia at different rates to fit the needs of different species of crop plants. This would allow all the ammonia produced to be used by the plants, rather than ending up washed into waterways.   


“Successful widespread adoption of these biofertilizers for farming would reduce pollution, provide sustainable ways of managing the nitrogen cycle in soil, lower production costs and increase profit margins for farmers and enhance sustainable food production by improving soil fertility,” said Mus.  


Reference: Mus F, Khokhani D, MacIntyre AM, et al. Genetic determinants of ammonium excretion in nifL mutants of Azotobacter vinelandii. Appli Enviro Microbiol. 0(ja):AEM.01876-21. doi:10.1128/AEM.01876-21


This article has been republished from the following materials. Note: material may have been edited for length and content. For further information, please contact the cited source.


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