Microbes and the Next Nitrogen Revolution

Pikaar, Ilje; Matassa, Silvio; Rabaey, Korneel; Bodirsky, Benjamin Leon; Popp, Alexander; Herrero, Mario; Verstraete, Willy

doi:10.1021/acs.est.7b00916

Cited by 86 publications

(56 citation statements)

References 51 publications

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“…Alternatively, studies point to microbial protein as a food source as the ultimate solution to tackle Nr pollution while sustaining the growing population. (Pikaar et al, 2018;Pikaar et al, 2017). Results for comparison between deposition level and the average CL are provided in Figure S13.…”

Section: Comparison Between Sulfur-nitrogen-combined Deposition and Cmentioning

confidence: 99%

Greater Contribution From Agricultural Sources to Future Reactive Nitrogen Deposition in the United States

et al. 2020

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Section: Comparison Between Sulfur-nitrogen-combined Deposition and Cmentioning

confidence: 99%

Greater Contribution From Agricultural Sources to Future Reactive Nitrogen Deposition in the United States

et al. 2020

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“…A long standing target for improvement in plant based agriculture is nitrogen fixation [ 76 , 77 ]. Nitrogen in a bioavailable form for crops is incredibly expensive to produce and environmentally costly, using 1% of the total annual world energy expenditure [ 78 ]. While plants are unable to fix atmospheric nitrogen, microbes can and do, particularly rhizobia in legumes.…”

Section: Opportunities For Plant-based Agriculture Through Innovatmentioning

confidence: 99%

Emerging Opportunities for Synthetic Biology in Agriculture

Goold

Wright

Hailstones

2018

Genes

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Rapid expansion in the emerging field of synthetic biology has to date mainly focused on the microbial sciences and human health. However, the zeitgeist is that synthetic biology will also shortly deliver major outcomes for agriculture. The primary industries of agriculture, fisheries and forestry, face significant and global challenges; addressing them will be assisted by the sector’s strong history of early adoption of transformative innovation, such as the genetic technologies that underlie synthetic biology. The implementation of synthetic biology within agriculture may, however, be hampered given the industry is dominated by higher plants and mammals, where large and often polyploid genomes and the lack of adequate tools challenge the ability to deliver outcomes in the short term. However, synthetic biology is a rapidly growing field, new techniques in genome design and synthesis, and more efficient molecular tools such as CRISPR/Cas9 may harbor opportunities more broadly than the development of new cultivars and breeds. In particular, the ability to use synthetic biology to engineer biosensors, synthetic speciation, microbial metabolic engineering, mammalian multiplexed CRISPR, novel anti microbials, and projects such as Yeast 2.0 all have significant potential to deliver transformative changes to agriculture in the short, medium and longer term. Specifically, synthetic biology promises to deliver benefits that increase productivity and sustainability across primary industries, underpinning the industry’s prosperity in the face of global challenges.

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“…The current lower production rates, compared to direct carboxylate production via fermentation, and subsequent high operational and capital cost, which are a factor of 5–10 higher than the actual value of, for example, acetate (Christodoulou and Velasquez‐Orta, ), do not yet enable economic application of electrosynthesis as such. As a final option, biogas can serve as a carbon and energy source to produce microbial protein as animal feed or even human food (Matassa et al , b; Pikaar et al , ). This can be carried out either directly by using methane as carbon and energy source for methane oxidizing bacteria (Strong et al , ; Verstraete et al , ) or indirectly as energy source to produce electricity for hydrogen gas production through water electrolysis for hydrogen oxidizing bacteria (Matassa et al , a).…”

Section: Engineering Of the Microbiomementioning

confidence: 99%

Taking the technical microbiome into the next decade

Vrieze

Boon

Verstraete

2018

Environmental Microbiology

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The 'microbiome' has become a buzzword. Multiple new technologies allow to gather information about microbial communities as they evolve under stable and variable environmental conditions. The challenge of the next decade will be to develop strategies to compose and manage microbiomes. Here, key aspects are considered that will be of crucial importance for future microbial technological developments. First, the need to deal not only with genotypes but also particularly with phenotypes is addressed. Microbial technologies are often highly dependent on specific core organisms to obtain the desired process outcome. Hence, it is essential to combine omics data with phenotypic information to invoke and control specific phenotypes in the microbiome. Second, the development and application of synthetic microbiomes is evaluated. The central importance of the core species is a no-brainer, but the implementation of proper satellite species is an important route to explore. Overall, for the next decade, microbiome research should no longer almost exclusively focus on its capacity to degrade and dissipate but rather on its remarkable capability to capture disordered components and upgrade them into high-value microbial products. These products can become valuable commodities in the cyclic economy, as reflected in the case of 'reversed sanitation', which is introduced here.

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Microbes and the Next Nitrogen Revolution

Cited by 86 publications

References 51 publications

Greater Contribution From Agricultural Sources to Future Reactive Nitrogen Deposition in the United States

Greater Contribution From Agricultural Sources to Future Reactive Nitrogen Deposition in the United States

Emerging Opportunities for Synthetic Biology in Agriculture

Taking the technical microbiome into the next decade

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