Root-induced changes in nutrient cycling in forests depend on exudation rates

Yin, Huajun; Wheeler, Emily C.; Phillips, Richard P.

doi:10.1016/j.soilbio.2014.07.022

Cited by 196 publications

(141 citation statements)

References 53 publications

(72 reference statements)

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“…Support for a positive effect of plants on N mining is provided by a range of studies that show higher activities of N-targeting enzymes, gross ammonification rates and soil N losses in rhizosphere than in non-rhizosphere soil (Brzostek et al 2013;Holz et al 2016;Kieloaho et al 2016;Koranda et al 2011;Weintraub et al 2007;Zhu et al 2014), a stimulation of N-targeting enzymes by artificial root exudates (Meier et al 2017), and positive correlations between rates of root exudation, SOC and (gross or net) N mineralization in experiments with intact plants (Bengtson et al 2012;Yin et al 2013Yin et al , 2014. The strongest support for a stimulation of microbial N mining by increased plant C input comes from experiments where plants were exposed to elevated CO 2 concentrations.…”

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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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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“…In the late plant growth season, the relatively small vegetation changes could be owed to the lack of treatment effects on soil enzyme activities and extractable nutrients. Labile C released through root exudation has been suggested to trigger positive plant-soil feedback via rhizosphere priming, which is an important mechanism that accounts for sustained forest growth during the experimental warming and CO 2 enrichment (Phillips et al, 2013;Yin et al, 2014). Thus, the low temperature and plant growth activity in the late plant growth season might substantially reduce the rhizodeposition, thereby hindered soil organic matter decomposition and subsequent nutrient cycling for further feedback on growth stimulation.…”

Section: Biotic Factors Affecting Ecosystem Responsesmentioning

confidence: 99%

Biotic and abiotic controls in determining exceedingly variable responses of ecosystem functions to extreme seasonal precipitation in a mesophytic alpine grassland

Sun

Wang

Zhu‐Barker

et al. 2016

Agricultural and Forest Meteorology

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a b s t r a c tAs a result of global climate change, frequent and intensive extreme climate events are observed and predicted. These extreme climate events can change ecosystem functions through driving plant growth and mortality, as well as ecological and evolutionary processes into different directions. We simulated a 1-in-100-year extreme precipitation event in different plant growth seasons (i.e. spring, summer, or autumn) to investigate the functional responses of a mesophytic alpine grassland ecosystem to climate change in the Tibetan plateau. The results demonstrated that the seasonal distribution of extreme precipitation is a critical factor in determining soil microbial-and plant-productivity. The response of vegetation net primary productivity (NPP) to extreme precipitation depends on the growth seasons and plant types. Total NPP in the treatments experienced extreme precipitation in the early (spring), mid-(summer) and late-(autumn) plant growth seasons were significant lower, higher, and no difference, respectively, compared with the control. Soil temperature and moisture were the key abiotic factors that affected ecosystem functions. For example, in the early plant growth season, no changes of soil moisture and the decreased temperature in response to the extreme precipitation resulted in a substantial decline in NPP. By contrast, in the mid-plant growth season, higher temperature and soil moisture elicited positive synergistic effects on plant growth and soil microbial processes. The increased sensitivity of above-ground NPP and the shift of dominant species from sedges to less palatable forbs might inevitably exaggerate the degradation of this grassland. Nevertheless, a high resilience index in the related ecological processes could potentially contribute to the grassland acclimation and stability, as most parameters returned to the similar levels as in the control after the extreme events ceased. Therefore, several synergistic or antagonistic mechanisms are hypothesized to operate in parallel or at different levels of organization and timescales. Further studies involving a range of different potential scenarios and longer periods are needed to predict the future climate change impacts on mesophytic grassland.

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“…The roots commonly grow deep into the rock fissures of the epikarst substratum (Huang et al 2011). A classification system is required for tree species based on the degree to which their roots alter nutrient availability and soil organic matter decomposition (Yin et al 2014).…”

Section: Environmental Factors Affecting Tree Regenerationmentioning

confidence: 99%

Environmental Factors Influencing Tree Species Regeneration in Different Forest Stands Growing on a Limestone Hill in Phrae Province, Northern Thailand

Asanok¹,

Marod²

2016

Journal of Forest and Environmental Science

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Improved knowledge of the environmental factors affecting the natural regeneration of tree species in limestone forest is urgently required for species conservation. We examined the environmental factors and tree species characteristics that are important for colonization in diverse forest stands growing on a limestone hill in northern Thailand. Our analysis estimated the relative influence of forest structure and environmental factors on the regeneration traits of tree species. We established sixty-four 100-m 2 plots in four forest stands on the limestone hill. We determined the species composition of canopy trees, regenerating seedlings, and saplings in relation to the physical environment. The relationships between environmental variables and tree species abundance were assessed by canonical correspondence analysis (CCA), and we used generalized linear mixed models to examine data on seedling/sapling abundances. The CCA ordination indicated that the abundance of tree species within the mixed deciduous forest was closely related to soil depth. The abundances of tree species growing within the sink-hole and hill-slope stands were positively related to the extent of rocky outcropping; light and soil moisture positively influenced the abundance of tree species in the hill-cliff stand. Physical factors had a greater effect on tree regeneration than did factors related to forest structure.Tree species, such as Ficus macleilandii, Dracaena cochinchinensis, and Phyllanthus mirabilis within the hill-cliff or sink-hole stand, colonized well on large rocky outcroppings that were well illuminated and had soft soils. These species regenerated well under conditions prevailing on the limestone hill. The colonization of several species in other stands was negatively influenced by environmental conditions at these sites. We found that natural regeneration of tree species on the limestone hill was difficult because of the prevailing combination of physical and biological factors. The influence of these factors was species dependent, and the magnitude of effects varied across forest stands.

show abstract

Root-induced changes in nutrient cycling in forests depend on exudation rates

Cited by 196 publications

References 53 publications

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

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

Biotic and abiotic controls in determining exceedingly variable responses of ecosystem functions to extreme seasonal precipitation in a mesophytic alpine grassland

Environmental Factors Influencing Tree Species Regeneration in Different Forest Stands Growing on a Limestone Hill in Phrae Province, Northern Thailand

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