Nitrogen addition promotes terrestrial plants to allocate more biomass to aboveground organs: A global meta‐analysis

Feng, Huili; Guo, Jiahuan; Peng, Changhui; Kneeshaw, Daniel; Roberge, Gabrielle; Pan, Chang; Ma, Xuehong; Zhou, Dan; Wang, Weifeng

doi:10.1111/gcb.16731

Cited by 25 publications

(13 citation statements)

References 337 publications

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“…Additionally, we found that N application significantly decreased root biomass and the ratio of root to leaf biomass (Figure 3b,c). These results suggest that D. involucrata saplings allocate less biomass to roots and more to leaves under N application conditions (Figure 3), which are in line with a recent global meta-analysis [66]. This response implies that D. involucrata saplings do not need to invest more biomass in roots under N application conditions, and increasing leaf biomass can enhance leaf photosynthetic rates and improve plant adaptation abilities to N application.…”

Section: Root Functional Traits Affected By N Applicationsupporting

confidence: 88%

The Impact of Nitrogen Application on Leaf and Root Functional Traits of Davidia involucrata Saplings

Liu,

Wen,

et al. 2023

Forests

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Understanding the effects of nitrogen (N) deposition on plant functional traits can provide insights into their adaptation strategies. We conducted an N application experiment (0, 5, 10, 15 g N m−2) with potted saplings of the endangered species Davidia involucrata and examined 24 functional traits of both leaves and roots. We found that N application increased the leaf morphological traits, except for a significant decrease (by 19.2%–27.0%) in specific leaf area (SLA). Compared to the control treatment, N application significantly increased the specific root surface area (SRA), specific root length (SRL), and root tissue density (RTD) by 9.2%–20.1%, 20.2%–47.9%, and 30.8%–46.4%, respectively, while root diameter was conservative and insensitive to N application. Additionally, N application had contrasting effects between leaf and root carbon, N, and phosphorus contents and their stoichiometry. SRL, SRA, and RTD were positively correlated with most leaf photosynthetic traits, but negatively correlated with SLA. Moreover, root biomass and root chemical traits were also tightly correlated with leaf photosynthetic traits and chemical traits. These results suggest that N application may trigger a resource-conservative strategy for leaves but a nutrient-acquisitive strategy for roots. Future N deposition combined with other practices, such as simultaneous P fertilizer application, can be effective for the scientific conservation of D. involucrata populations in their natural habitats.

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Section: Root Functional Traits Affected By N Applicationsupporting

confidence: 88%

The Impact of Nitrogen Application on Leaf and Root Functional Traits of Davidia involucrata Saplings

Liu,

Wen,

et al. 2023

Forests

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“…Yue et al (2021) discovered that N addition significantly increased the root mass fraction and had no significant effect on leaf and stem mass fraction. In contrast, Feng et al (2023) reported a noteworthy increase in both leaf and stem mass fraction of terrestrial plant under N addition, while the root mass fraction was decreased by 14.7%. Unlike biomass, newly assimilated C can be utilized in various ways: it may be stored as carbohydrates, facilitate tissue growth, or serve as an energy source for plants (Halford, 2010).…”

mentioning

confidence: 75%

“…Furthermore, N addition can also stimulate biomass allocation to nutrient organs. Under ample N supply, terrestrial plants augment both specific leaf areas and leaf areas per plant, thus enhancing their light‐capturing capabilities (Feng et al., 2023). These results are consistent with previous findings and support the optimal partitioning theory, which suggests that more assimilated C is allocated to aboveground tissues when nutrient limitation is alleviated (Grechi et al., 2007; Reynolds & Thornley, 1982).…”

Section: Discussionmentioning

confidence: 99%

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Trade‐off in the partitioning of recent photosynthate carbon under global change

Li,

Qing,

et al. 2023

Global Change Biology

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There may be trade‐offs in the allocation patterns of recent photosynthetic carbon (RPC) allocation in response to environmental changes, with a greater proportion of RPC being directed towards compartments experiencing limited resource availability. Alternatively, the allocation of RPC could shift from sources to sinks as plants processing excess photosynthates. It prompts the question: Does the pattern of RPC allocation vary under global changes? If so, is this variation driven by optimal or by residual C allocation strategies? We conducted a meta‐analysis by complicating 273 pairwise observations from 55 articles with 13C or 14C pulse or continuous labeling to assess the partitioning of RPC in biomass (leaf, stem, shoot, and root), soil pools (soil organic C, rhizosphere, and microbial biomass C) and CO2 fluxes under elevated CO2 (eCO2), warming, drought and nitrogen (N) addition. We propose that the increased allocation of RPC to belowground under sufficient CO2 results from the excretion of excess photosynthates. Warming led to a significant reduction in the percentage of RPC allocated to shoots, alongside an increase in roots allocation, although this was not statistically significant. This pattern is due to the reduced water availability resulting from warming. In conditions of drought, there was a notable increase in the partitioning of RPC to stems (+7.25%) and roots (+36.38%), indicative of a greater investment of RPC in roots for accessing water from deeper soil. Additionally, N addition led to a heightened allocation of RPC in leaves (+10.18%) and shoots (+5.78%), while reducing its partitioning in soil organic C (−8.92%). Contrary to the residual C partitioning observed under eCO2, the alterations in RPC partitioning in response to warming, drought, and N supplementation are more comprehensively explained through the lens of optimal partitioning theory, showing a trade‐off in the partitioning of RPC under global change.

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“…N deposition, an important driver of global changes, generally increases soil N pools but decreases soil P pools (Deng et al., 2017; Jian et al., 2016; Lu et al., 2011; Luo et al., 2022). It is significantly altering the quantity and quality of litter input by regulating plant primary production and nutrient allocation (H. Feng et al., 2023; LeBauer & Treseder, 2008; Xia & Wan, 2008). These changes increase the complexity and uncertainty in predicting how soil N and P pools respond to litter input.…”

Section: Introductionmentioning

confidence: 99%

Responses of Soil Nitrogen Pools to Litter Input Under Nitrogen Addition: A Meta‐Analysis

Yang,

Wu,

et al. 2024

JGR Biogeosciences

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Litter input essentially regulates soil nitrogen (N) and phosphorus (P) pools in natural ecosystems, but uncertainties remain about how this regulation is affected by increasing N deposition. Here, we synthesized 1,263 observations from 34 field studies with paired treatments to elucidate how N addition affects the responses of soil N and P pools to litter input. Our results showed that the combination of litter input and N addition significantly enhanced soil N pools, with increases in total N (13.7%), microbial biomass N (38.7%), ammonium N (37.7%), and nitrate N (79.0%), but slightly affected soil P pools. Strikingly, soil N pools in forests displayed more positive responses to combined treatment than those in grasslands. Furthermore, experimental design and mean annual precipitation were critical controllers in regulating the responses of soil N pools to combined litter input and N addition. The present results underscore the importance of combined litter input and N addition in promoting soil N pools, thereby providing essential insights into how N addition can change nutrient cycling within natural ecosystems.

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Nitrogen addition promotes terrestrial plants to allocate more biomass to aboveground organs: A global meta‐analysis

Cited by 25 publications

References 337 publications

The Impact of Nitrogen Application on Leaf and Root Functional Traits of Davidia involucrata Saplings

The Impact of Nitrogen Application on Leaf and Root Functional Traits of Davidia involucrata Saplings

Trade‐off in the partitioning of recent photosynthate carbon under global change

Responses of Soil Nitrogen Pools to Litter Input Under Nitrogen Addition: A Meta‐Analysis

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