Mycorrhizal association as a primary control of the CO
            <sub>2</sub>
            fertilization effect

Terrer, César; Vicca, Sara; Hungate, Bruce A.; Phillips, Richard P.; Prentice, Iain Colin

doi:10.1126/science.aaf4610

Cited by 483 publications

(393 citation statements)

References 138 publications

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“…This idea gained recent support by Terrer et al (2016) who found that plant species colonized by ECM fungi were able to sustain increased growth under elevated concentrations of carbon dioxide despite low soil N availability a phenomenon that has also been reported by others (Drake et al 2011). One possible mechanism for this sustained growth response is that ECM fungi, supplied with additional C from host plants, are able to mine recalcitrant compounds for N thereby increasing plant N uptake (Phillips et al 2012;Terrer et al 2016). To gain a more complete picture of the organisms and conditions driving the decomposition of the most distal root orders, there are a number of questions that require answers (Table 1).…”

Section: Final Thoughtsmentioning

confidence: 89%

Maintaining connectivity: understanding the role of root order and mycelial networks in fine root decomposition of woody plants

Beidler

Pritchard

2017

Plant Soil

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Background The predictive power of climate models is limited by an incomplete understanding of the controls on fine root decomposition and thus belowground carbon cycling. To more accurately model rates of decay, fine root heterogeneity needs to be addressed in fine root decomposition studies. Branching order integrates both structural and chemical properties that are important in indicating litter quality and decay rate. Scope We discuss current views on the controls and patterns of fine root decomposition in combination with recent findings related to the effects of branching order and mycorrhizal decomposition. We examine the counterintuitive finding that nitrogen rich, lower order roots decompose more slowly than woody, higher order roots in temperate and subtropical forests. ConclusionsWe posit that slower decomposition of first and second compared to higher order roots might be caused by the poor carbon quality associated with higher concentrations of phenols in lower order roots or by inhibition of saprophytes by the mycorrhizal fungi that often preferentially inhabit these roots. Alternatively, apparent recalcitrance of lower order roots could be an experimental artifact caused by severing pre-mortem mycelial connections during sample processing, or exclusion of animals that graze fungal structures by the small mesh sizes characteristic of litterbags. To better predict the residence time of the carbon contained in the entire fine root pool, existing methods should be applied to individual root orders when practical. New methods for characterizing decomposition of undisturbed roots that have senesced naturally are greatly needed.

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Section: Final Thoughtsmentioning

confidence: 89%

Maintaining connectivity: understanding the role of root order and mycelial networks in fine root decomposition of woody plants

Beidler

Pritchard

2017

Plant Soil

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“…However, a stimulation of enzyme synthesis by N was not observed in this study (Table 2), and (4) finally, microbial N mining might depend on the association of plants with mycorrhizal fungi, an effect that we would have underestimated in our laboratory experiment. Ectomycorrhiza-the dominant mycorrhiza in boreal forests-have been linked to the release of available N from SOM polymers (Lindahl et al 2007;Talbot et al 2013), and to increased N mining under elevated CO 2 (Drake et al 2011;Terrer et al 2016). Microbial N mining might thus depend not on plantsoil C allocation in general, but specifically on the allocation of C to certain mycorrhiza.…”

Section: Discussionmentioning

confidence: 99%

Short-term carbon input increases microbial nitrogen demand, but not microbial nitrogen mining, in a set of boreal forest soils

et al. 2017

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“…Janssens et al, 2010;Vicca et al, 2012;Fernández-Martínez et al, 2014). Moreover, nutrient availability can modify ecosystem responses to global atmospheric and climatic changes, such as nitrogen (N) deposition (From et al, 2016), increasing CO2 levels (Norby et al, 2010;Terrer et al, 2016), warming (Dieleman et al, 2012) and drought (Friedrich et al, Biogeosciences Discuss., https://doi.org/10.5194/bg-2017-372 Manuscript under review for journal Biogeosciences Discussion started: 2 November 2017 c Author(s) 2017. CC BY 4.0 License.…”

Section: Introductionmentioning

confidence: 99%

The influence of soil properties and nutrients on conifer forest growth in Sweden, and the first steps in developing a nutrient availability metric

Sundert¹,

Horemans²,

Stendahl³

et al. 2017

Preprint

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Abstract. The availability of nutrients regulates terrestrial carbon cycling and modifies ecosystem responses to environmental changes. Nonetheless, nutrient availability is often overlooked in climate-carbon cycle studies because it depends on the interplay of various soil factors that would ideally be comprised into one metric. Such a metric does not currently exist. Here, 10 we used a Swedish forest inventory database that contains soil and tree growth data for >2500 forests across Sweden to test which combination soil factors best explains variation in plant growth, and to take the first steps in developing a nutrient availability metric. For the latter, we started from a (yet unvalidated) metric for constraints on nutrient availability that was previously developed by IIASA (Laxenburg, Austria). This IIASA-metric was developed for crops and uses only indirect indicators of nutrient availability. Our analyses revealed that soil organic carbon content (SOC) and the soil carbon to nitrogen 15 (C:N) ratio were the most important factors explaining variation in "normalized" (climate-independent) productivity.Normalized productivity increased with decreasing soil C:N ratio (R² = 0.02-0.13), while SOC exhibited an empirical optimum (R² = 0.05-0.15). The IIASA-metric was unrelated to normalized productivity (R² = 0.00-0.01), because the soil factors under consideration were not well implemented, and because the C:N ratio was not included. We upgraded this metric by incorporating soil C:N and adjusting the relationship between SOC and nutrient availability in view of the observed 20 relationship across our database. This upgraded metric explained a significant fraction of the variation (R² = 0.03-0.21; depending on the applied method) and thus opens up new opportunities to further validate and improve it with other datasets, from forests and from other ecosystem types, to ultimately develop a generic global nutrient availability metric.

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Mycorrhizal association as a primary control of the CO ₂ fertilization effect

Cited by 483 publications

References 138 publications

Maintaining connectivity: understanding the role of root order and mycelial networks in fine root decomposition of woody plants

Maintaining connectivity: understanding the role of root order and mycelial networks in fine root decomposition of woody plants

Short-term carbon input increases microbial nitrogen demand, but not microbial nitrogen mining, in a set of boreal forest soils

The influence of soil properties and nutrients on conifer forest growth in Sweden, and the first steps in developing a nutrient availability metric

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Mycorrhizal association as a primary control of the CO 2 fertilization effect

Cited by 483 publications

References 138 publications

Maintaining connectivity: understanding the role of root order and mycelial networks in fine root decomposition of woody plants

Maintaining connectivity: understanding the role of root order and mycelial networks in fine root decomposition of woody plants

Short-term carbon input increases microbial nitrogen demand, but not microbial nitrogen mining, in a set of boreal forest soils

The influence of soil properties and nutrients on conifer forest growth in Sweden, and the first steps in developing a nutrient availability metric

Contact Info

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Resources

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Mycorrhizal association as a primary control of the CO ₂ fertilization effect