Long‐term agricultural management does not alter the evolution of a soybean–rhizobium mutualism

Schmidt, Jennifer E.; Weese, Dylan J.; Lau, Jennifer A.

doi:10.1002/eap.1625

Cited by 9 publications

(4 citation statements)

References 52 publications

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“…However, these models assume plants can consistently sanction even moderately less‐beneficial strains when soil N is available, which have not been widely reported. In field studies, while long‐term addition of nitrogen may decrease the relative abundance of beneficial rhizobial genotypes, perhaps by decreasing legume abundance (Weese, Heath, Dentinger, & Lau, 2015), Schmidt, Weese, and Lau (2017) found little effect of crop management on rhizobial mutualism, suggesting that elevated levels of soil nitrogen does not select for poor‐fixing rhizobia. However, crop management treatments alter multiple parameters, such as soil structure and organic content, that could confound the effects of fertilizer on rhizobial evolution.…”

Section: Introductionmentioning

confidence: 99%

How do less‐expensive nitrogen alternatives affect legume sanctions on rhizobia?

Oono

Muller

et al. 2020

Ecology and Evolution

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Section: Introductionmentioning

confidence: 99%

How do less‐expensive nitrogen alternatives affect legume sanctions on rhizobia?

Oono

Muller

et al. 2020

Ecology and Evolution

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“…Growing in the presence of soy hosts could have selected for strains that are less beneficial for alternate hosts like Chamaecrista, as different legume species have been shown to be compatible with the same rhizobia but vary in the benefits they derive from them (Pahua et al, 2018). And while the Lux site now has lower soil nitrogen availability, prior fertilizer inputs could have led to the evolution of less beneficial mutualists that might still persist today (Corkidi, Rowland, Johnson, & Allen, 2002, Johnson, 1993, Weese et al, 2015, but see Schmidt, Weese, & Lau, 2017).…”

Section: Discussionmentioning

confidence: 99%

Novel plant–microbe interactions: Rapid evolution of a legume–rhizobium mutualism in restored prairies

Magnoli

Lau

2020

Journal of Ecology

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“…Typically researchers have studied how rhizobia vary in terms of their effects on whole-plant traits (Burdon et al, 1999;Heath, 2010;Barrett et al, 2012;Porter and Simms, 2014) or the instantaneous rate of N fixation via acetylene reduction assays (McNeil, 1982;Minchin et al, 1983;Tan and Tan, 1986). Ecosystem ecologists and ecophysiologists have long used isotope abundances (natural or enriched) to study biological N fixation in the field (Shearer and Kohl, 1986;Mead and Preston, 2011;Yelenik et al, 2013;Craine et al, 2015) or greenhouse (Menge et al, 2015;Taylor and Menge, 2018), but mutualism research increasingly features the use of isotope abundance (natural or enriched) to study the trade of benefits in resource mutualisms (Ruess et al, 2013;Regus et al, 2017;Schmidt et al, 2017;Taylor and Menge, 2018). Ruess et al (2013) estimated nodule respiration, N fixation, and Frankia strain identity in a field survey of Alnus tenuifolia and found that Frankia strains vary in terms of both N fixation and respiratory cost.…”

Section: Rhizobium Variation Mediates Host Plant Responses To Lightmentioning

confidence: 99%

Light availability and rhizobium variation interactively mediate the outcomes of legume–rhizobium symbiosis

Heath

Podowski

Heniff

et al. 2020

American J of Botany

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Premise Nutrients, light, water, and temperature are key factors limiting the growth of individual plants in nature. Mutualistic interactions between plants and microbes often mediate resource limitation for both partners. In the mutualism between legumes and rhizobia, plants provide rhizobia with carbon in exchange for fixed nitrogen. Because partner quality in mutualisms is genotype‐dependent, within‐species genetic variation is expected to alter the responses of mutualists to changes in the resource environment. Here we ask whether partner quality variation in rhizobia mediates the response of host plants to changing light availability, and conversely, whether light alters the expression of partner quality variation. Methods We inoculated clover hosts with 11 strains of Rhizobium leguminosarum that differed in partner quality, grew plants under either ambient or low light conditions in the greenhouse, and measured plant growth, nodule traits, and foliar nutrient composition. Results Light availability and rhizobium inoculum interactively determined plant growth, and variation in rhizobium partner quality was more apparent in ambient light. Conclusions Our results suggest that variation in the costs and benefits of rhizobium symbionts mediate host responses to light availability and that rhizobium strain variation might more important in higher‐light environments. Our work adds to a growing appreciation for the role of microbial intraspecific and interspecific diversity in mediating extended phenotypes in their hosts and suggests an important role for light availability in the ecology and evolution of legume–rhizobium symbiosis.

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Long‐term agricultural management does not alter the evolution of a soybean–rhizobium mutualism

Cited by 9 publications

References 52 publications

How do less‐expensive nitrogen alternatives affect legume sanctions on rhizobia?

How do less‐expensive nitrogen alternatives affect legume sanctions on rhizobia?

Novel plant–microbe interactions: Rapid evolution of a legume–rhizobium mutualism in restored prairies

Light availability and rhizobium variation interactively mediate the outcomes of legume–rhizobium symbiosis

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