Agritech to Tame the Nitrogen Cycle.

IF 6.9 2区 生物学 Q1 CELL BIOLOGY Cold Spring Harbor perspectives in biology Pub Date : 2024-03-01 DOI:10.1101/cshperspect.a041668
Lisa Y Stein
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Abstract

While the Haber-Bosch process for N-fixation has enabled a steady food supply for half of humanity, substantial use of synthetic fertilizers has caused a radical unevenness in the global N-cycle. The resulting increases in nitrate production and greenhouse gas (GHG) emissions have contributed to eutrophication of both ground and surface waters, the growth of oxygen minimum zones in coastal regions, ozone depletion, and rising global temperatures. As stated by the Food and Agriculture Organization of the United Nations, agriculture releases ∼9.3 Gt CO2 equivalents per year, of which methane (CH4) and nitrous oxide (N2O) account for 5.3 Gt CO2 equivalents. N-pollution and slowing the runaway N-cycle requires a combined effort to replace chemical fertilizers with biological alternatives, which after a 10-yr span of usage could eliminate a minimum of 30% of ag-related GHG emissions (∼1.59 Gt), protect waterways from nitrate pollution, and protect soils from further deterioration. Agritech solutions include bringing biological fertilizers and biological nitrification inhibitors to the marketplace to reduce the microbial conversion of fertilizer nitrogen into GHGs and other toxic intermediates. Worldwide adoption of these plant-derived molecules will substantially elevate nitrogen use efficiency by crops while blocking the dominant source of N2O to the atmosphere and simultaneously protecting the biological CH4 sink. Additional agritech solutions to curtail N-pollution, soil erosion, and deterioration of freshwater supplies include soil-free aquaponics systems that utilize improved microbial inocula to enhance nitrogen use efficiency without GHG production. With adequate and timely investment and scale-up, microbe-based agritech solutions emphasizing N-cycling processes can dramatically reduce GHG emissions on short time lines.

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Agritech将驯服氮循环。
虽然Haber Bosch固定氮工艺为一半的人类提供了稳定的粮食供应,但大量使用合成肥料导致了全球氮循环的根本不均衡。由此导致的硝酸盐产量和温室气体排放的增加导致了地下水和地表水的富营养化、沿海地区氧气最低区的增加、臭氧消耗和全球气温上升。根据联合国粮食及农业组织的说法,农业每年释放约9.3 Gt二氧化碳当量,其中甲烷(CH4)和一氧化二氮(N2O)占5.3 Gt二氧化碳等价物。氮污染和减缓失控的氮循环需要综合努力,用生物替代品取代化肥,在使用10年后,可以消除至少30%的与氮相关的温室气体排放(~1.59 Gt),保护水道免受硝酸盐污染,并保护土壤免受进一步恶化。Agritech的解决方案包括将生物肥料和生物硝化抑制剂推向市场,以减少微生物将肥料氮转化为温室气体和其他有毒中间体。在全球范围内采用这些植物衍生分子将大大提高作物的氮利用效率,同时阻断N2O向大气的主要来源,同时保护生物CH4汇。减少氮污染、土壤侵蚀和淡水供应恶化的其他农业技术解决方案包括无土壤水培系统,该系统利用改进的微生物接种物来提高氮利用效率,而不会产生温室气体。通过充分及时的投资和扩大规模,强调氮循环过程的基于微生物的农业技术解决方案可以在短时间内大幅减少温室气体排放。
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来源期刊
CiteScore
15.00
自引率
1.40%
发文量
56
审稿时长
3-8 weeks
期刊介绍: Cold Spring Harbor Perspectives in Biology offers a comprehensive platform in the molecular life sciences, featuring reviews that span molecular, cell, and developmental biology, genetics, neuroscience, immunology, cancer biology, and molecular pathology. This online publication provides in-depth insights into various topics, making it a valuable resource for those engaged in diverse aspects of biological research.
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