Economics and Agronomics of Relay‐Cropping Pennycress and Camelina with Soybean in Minnesota

Ott, Matthew; Eberle, Carrie A.; Thom, Matt D.; Archer, David W.; Forcella, Frank; Gesch, Russ W.; Wyse, Donald L.

doi:10.2134/agronj2018.04.0277

Cited by 54 publications

(83 citation statements)

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“…Potential benefits of cover crops do need to be evaluated against potential liabilities. Although autumn sequestration of N by winter rye and radish was pronounced, neither treatment indicated positive or negative effects, as soybean yields in these treatments were not statistically different than yields under fallow treatments (Ott et al, 2018). This indicates that neither sequestration, immobilization with decaying biomass, nor potential loss of nutrients from the system were of consequence in winter rye or radish.…”

Section: Discussionmentioning

confidence: 97%

“…This indicates that neither sequestration, immobilization with decaying biomass, nor potential loss of nutrients from the system were of consequence in winter rye or radish. However, double‐cropping oilseeds with soybean did cause a delay in soybean growth, and a reduction in soybean yields (Ott et al, 2018). On the other hand, the total production of both crops, particularly for oil content, can exceed that of monoculture soybeans, which might provide an economic incentive for adoption (Gesch et al, 2014; Berti et al, 2015; Ott et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

“…However, double‐cropping oilseeds with soybean did cause a delay in soybean growth, and a reduction in soybean yields (Ott et al, 2018). On the other hand, the total production of both crops, particularly for oil content, can exceed that of monoculture soybeans, which might provide an economic incentive for adoption (Gesch et al, 2014; Berti et al, 2015; Ott et al, 2018). This combination of economic viability, environmental benefits such as floral resources for pollinators (Eberle et al, 2015; Thom et al, 2018), and the potential to reduce nutrient loss, which was established by N and P uptake and soil and soil‐water dynamics in the current study, indicates that autumn‐seeded, overwintering oilseed crops can provide an opportunity to increase cropping system diversity and improve economic and environmental outcomes.…”

Section: Discussionmentioning

confidence: 99%

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Reduced Potential for Nitrogen Loss in Cover Crop–Soybean Relay Systems in a Cold Climate

et al. 2019

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Winter cover crops might reduce nutrient loss to leaching in the Upper Midwest. New oilseed‐bearing cash cover crops, such as winter camelina (Camelina sativa L.) and pennycress (Thlaspi arvense L.), may provide needed incentives. However, the abilities of these crops to sequester labile soil nutrients are unknown. To address this unknown, N in shoot biomass, plant‐available N and P in soil, and NO3−–N and soluble reactive P in soil water collected from lysimeters placed at 30, 60, and 100 cm were measured in cover crop and fallow treatments established in spring wheat (Triticum aestivum L.) stubble and followed through a cover crop–soybean [Glycine max (L.) Merr.] rotation. Five no‐till cover treatments (forage radish [Raphanus sativus L.], winter rye [Secale cereale L.], field pennycress, and winter camelina) were compared with two fallow treatments (chisel till and no‐till). Pennycress and winter camelina were harvested at maturity after relay sowing of soybean. Winter rye and radish sequestered more N in autumn shoot biomass, ranging from 26 to 38 kg N ha−1, but overwintering oilseeds matched or exceeded N uptake in spring, ranging 28 to 49 kg N ha−1 before soybean planting. Nitrogen uptake was reflected by reductions in soil water NO3−–N during cover crop and intercropping phases for all cover treatments (mean = 4 mg L−1), compared with fallow treatments (mean = 31 mg L−1). Cash cover crops like pennycress and winter camelina provide both environmental and potential economic resources to growers. They are cash‐generating crops able to sequester labile soil nutrients, which protects and promotes soil health from autumn through early summer. Core Ideas Alternative, easily established winter‐surviving covers are needed in the Upper Midwest. Cover crops sequestered N and reduced soil and soil water NO3−–N in autumn compared with fallow. Winter oilseed crops reduced soil water NO3−–N in autumn through soybean planting. Novel winter oilseeds provide environmental and economic incentives to enhance adoption.

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Section: Discussionmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Reduced Potential for Nitrogen Loss in Cover Crop–Soybean Relay Systems in a Cold Climate

et al. 2019

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“…Our results suggest that cover crop breeding research should shift to emphasize increased seed yield. Only a handful of cover crops are actively being bred for seed productivity (i.e., Pennycress and Camelina; [17]). Most breeding has focused on ecosystem service values [9] and forage quality [11], with seed yields holding little to no priority.…”

Section: Main Textmentioning

confidence: 99%

The hidden land use cost of upscaling cover crops

Runck

Khoury

Ewing

et al. 2020

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“…Pennycress grown as a cover can reduce nutrient leaching and soil erosion and reduce the growth of spring weeds (Johnson et al ., ; Thom et al ., ). In addition, as an oilseed, pennycress holds great promise as a new cover crop that can provide an economic return to rural communities (Ott et al ., ).…”

Section: Introductionmentioning

confidence: 97%

Translational genomics using Arabidopsis as a model enables the characterization of pennycress genes through forward and reverse genetics

et al. 2018

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Thlaspi arvense (pennycress) has the potential for domestication as a new oilseed crop. Information from an extensive body of research on the related plant species Arabidopsis can be used to greatly speed this process. Genome-scale comparisons in this paper documented that pennycress and Arabidopsis share similar gene duplication. This finding led to the hypothesis that it should be possible to isolate Arabidopsis-like mutants in pennycress. This proved to be true, as forward genetic screens identified floral and vegetative pennycress mutants that were similar to mutants found in Arabidopsis. Extending this approach, it was shown that most of the pennycress genes responsible for the formation of oxidized tannins could be rapidly identified. The causative mutations in the pennycress mutants could be identified either by PCR amplification of candidate genes or through whole-genome sequencing (WGS) analysis. In all, WGS was used to characterize 95 ethyl methane sulfonate mutants, which revealed a mutation rate of 4.09 mutations per megabase. A sufficient number of non-synonymous mutations were identified to create a mutant gene index that could be used for reverse genetic approaches to identify pennycress mutants of interest. As proof of concept, a Ta-max3-like dwarf mutant and Ta-kcs5/cer60-like wax mutants deficient in the biosynthesis of long chain fatty acids were identified. Overall, these studies demonstrate that translational genomics can be used to promote the domestication of pennycress. Furthermore, the ease with which important findings could be made in pennycress makes this species a new potential model plant.

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Economics and Agronomics of Relay‐Cropping Pennycress and Camelina with Soybean in Minnesota

Cited by 54 publications

References 38 publications

Reduced Potential for Nitrogen Loss in Cover Crop–Soybean Relay Systems in a Cold Climate

Reduced Potential for Nitrogen Loss in Cover Crop–Soybean Relay Systems in a Cold Climate

The hidden land use cost of upscaling cover crops

Translational genomics using Arabidopsis as a model enables the characterization of pennycress genes through forward and reverse genetics

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