Elevated atmospheric carbon dioxide and ozone alter soybean diseases at SoyFACE

Eastburn, Darin M.; Degennaro, Melissa M.; DeLucia, Evan H.; Dermody, Orla; McElrone, Andrew J.

doi:10.1111/j.1365-2486.2009.01978.x

Cited by 119 publications

(101 citation statements)

References 34 publications

(69 reference statements)

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“…This can lead to increased levels of foliar diseases that are favored by moist conditions. For example, brown spot, caused by Septoria glycines, can start moving up the canopy earlier on soybeans planted in narrow rows [38]. High plant populations can also make soybeans more susceptible to diseases such as charcoal rot and Sclerotinia stem rot.…”

Section: Planting Dates and Densitiesmentioning

confidence: 99%

Organically Grown Soybean Production in the USA: Constraints and Management of Pathogens and Insect Pests

et al. 2016

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Soybean is the most produced and consumed oil seed crop worldwide. In 2013, 226 million metric tons were produced in over 70 countries. Organically produced soybean represents less than 0.1% of total world production. In the USA, the certified organic soybean crop was grown on 53 thousand ha or 0.17% of the total soybean acreage in the USA (32 million ha) in 2011. A gradual increase in production of organically grown soybean has occurred since the inception of organic labeling due to increased human consumption of soy products and increased demand for organic soybean meal to produce organic animal products. Production constraints caused by pathogens and insect pests are often similar in organic and non-organic soybean production, but management between the two systems often differs. In general, the non-organic, grain-type soybean crop are genetically modified higher-yielding cultivars, often with disease and pest resistance, and are grown with the use of synthetic pesticides. The higher value of organically produced soybean makes production of the crop an attractive option to some farmers. This article reviews production and uses of organically grown soybean in the USA, potential constraints to production caused by pathogens and insect pests, and management practices used to reduce the impact of these constraints.

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Section: Planting Dates and Densitiesmentioning

confidence: 99%

Organically Grown Soybean Production in the USA: Constraints and Management of Pathogens and Insect Pests

et al. 2016

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“…Several studies in open-top field chambers indicated that soybean yield has already been under threat at current O 3 concentrations [3,8], with dramatic yield loss of 53% by ambient air in Pakistan [9]. An increase of O 3 concentration from 30 to 60 ppb for 7 h day −1 could decrease soybean yield by 16% [10], and greater yield loss under higher O 3 concentration [11].…”

Section: Introductionmentioning

confidence: 99%

Effects of elevated O3 exposure on seed yield, N concentration and photosynthesis of nine soybean cultivars (Glycine max (L.) Merr.) in Northeast China

et al. 2014

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a b s t r a c tNine soybean cultivars widely cultivated in Northeast China were investigated in present study to assess their O 3 sensitivities on the basis of the response of photosynthesis and seed yield to ambient and future ozone (O 3 ) concentrations, and determine whether the effects of O 3 vary with the developmental stages (flowering and seed filling stages). Relative to charcoal-filtered air (CF), elevated O 3 concentration (E-O 3 , ambient air + 40 ppb) significantly reduced soybean yields by 40%, with a range of 32-46% among cultivars. E-O 3 also induced significant decreases in pigment contents, net photosynthetic rate and chlorophyll a fluorescence at both flowering and seed filling stages in most cultivars. Except net photosynthetic rate and stomatal conductance (g s ) at seed filling stage, all variables showed no significant interaction between O 3 and cultivar, suggesting that all tested cultivars had similar sensitivities to O 3 . The responses of seed N content to E-O 3 differed among cultivars. Ambient O 3 concentration (mean of daily concentration of 19 ppb) did not induce any change relative to CF. Significant positive relationship between endogenous g s in CF and yield loss among cultivars was found only at seed filling stage. Positive correlation between effects of E-O 3 on leaf N content and effects on light saturated photosynthetic rate (A sat ) indicated that g s and leaf N content at seed filling stage contributes to yield loss and decreased photosynthesis by E-O 3 , respectively. It can be inferred that E-O 3 had a larger negative effects on seed filling stage than flowering stage of soybean.

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“…Phytophthora citricola on Fagus sylvatica seedlings under elevated CO 2 and N fertilization; Fleischmann et al 2010). Free-Air CO 2 Enrichment (FACE) facilities can deliver useful insights on how plant pathosystems are likely to be affected by the interactions among global change factors (Eastburn et al 2009(Eastburn et al , 2011. There is a need to include in such studies various plant disease management approaches, including The pathogen was introduced into Switzerland from SouthWest Germany in the 1980s (this explains why the climatically more suitable Ticino has been less affected by fire blight than northern Swiss Cantons).…”

Section: Interactions Among Global Change Factorsmentioning

confidence: 99%

Impacts of climate change on plant diseases—opinions and trends

et al. 2012

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There has been a remarkable scientific output on the topic of how climate change is likely to affect plant diseases. This overview addresses the need for review of this burgeoning literature by summarizing opinions of previous reviews and trends in recent studies on the impacts of climate change on plant health. Sudden Oak Death is used as an introductory case study: Californian forests could become even more susceptible to this emerging plant disease, if spring precipitations will be accompanied by warmer temperatures, although climate shifts may also affect the current synchronicity between host cambium activity and pathogen colonization rate. A summary of observed and predicted climate changes, as well as of direct effects of climate change on pathosystems, is provided. Prediction and management of climate change effects on plant health are complicated by indirect effects and the interactions with global change drivers. Uncertainty in models of plant disease development under climate change calls for a diversity of management strategies, from more participatory approaches to interdisciplinary science. Involvement of stakeholders and scientists from outside plant pathology shows the importance of trade-offs, for example in the land-sharing vs. sparing debate. Further research is needed on climate change and plant health in mountain, boreal, Mediterranean and tropical regions, with multiple climate change factors and scenarios (including our responses to it, e.g. the assisted migration of plants), in relation to endophytes, viruses and mycorrhiza, using long-term and large-scale datasets and considering various plant disease control methods.Keywords Adaptive ecosystem management . Biotic interactions . Landscape pathology . Phytophthora ramorum . Plant disease epidemiology . Tree fungal pathogens Up to the 1990s, there was little information about climate change impacts on plant disease. For example, Eur J Plant Pathol

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Elevated atmospheric carbon dioxide and ozone alter soybean diseases at SoyFACE

Cited by 119 publications

References 34 publications

Organically Grown Soybean Production in the USA: Constraints and Management of Pathogens and Insect Pests

Organically Grown Soybean Production in the USA: Constraints and Management of Pathogens and Insect Pests

Effects of elevated O3 exposure on seed yield, N concentration and photosynthesis of nine soybean cultivars (Glycine max (L.) Merr.) in Northeast China

Impacts of climate change on plant diseases—opinions and trends

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