Resource colimitation governs plant community responses to altered precipitation

Eskelinen, Anu; Harrison, Susan

doi:10.1073/pnas.1508170112

Cited by 109 publications

(139 citation statements)

References 63 publications

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“…The PCA and the change in the relative AGB of the PFGs also indicated that the shift patterns were mainly derived from precipitation changes. The findings agree with some other studies reported that altered precipitation notably shifted plant community composition in semiarid grasslands (Eskelinen & Harrison, ; Yang et al, ). However, the sensitivity of plant community composition to precipitation changes could be mediated by other limited resource such as N, largely depending on environmental conditions such as soil nutrient pools (Eskelinen & Harrison, ).…”

Section: Discussionsupporting

confidence: 93%

Nitrogen deposition magnifies the sensitivity of desert steppe plant communities to large changes in precipitation

et al. 2019

Journal of Ecology

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Precipitation alteration and nitrogen (N) deposition caused by anthropogenic activities could profoundly affect the structure and functioning of plant communities in arid ecosystems. However, the plant community impacts conferred by large temporal changes in precipitation, especially with a concurrent increase in N deposition, remain unclear. To address this uncertainty, from 2016 to 2017, an in situ field experiment was conducted to examine the effects of five precipitation levels, two N levels and their interaction on the plant community function and composition in a desert steppe in northern China. Above‐ground net primary production (ANPP) and plant community‐weighted mean (CWM) height significantly increased with increasing precipitation, and both were well fitted with a positive linear model, but with a higher slope under N addition. The ANPP increase was primarily driven by the increase in Artemisia capillaris, a companion forb sensitive to precipitation variation. The plant community composition shifted with precipitation enhancement—from a community dominated by Stipa tianschanica, a perennial grass, to a community dominated by Artemisia capillaris. Synthesis. The findings imply that the ecosystem sensitivity to future changes in precipitation variability will be mediated by two potential mechanisms: concurrent N deposition and plant community‐level change. It is suggested that we should consider the vegetation compositional shift and multiple resource colimitation in assessing the sensitivity of terrestrial ecosystems to climate change.

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Section: Discussionsupporting

confidence: 93%

Nitrogen deposition magnifies the sensitivity of desert steppe plant communities to large changes in precipitation

et al. 2019

Journal of Ecology

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“…Fen and bog vegetation respond contrastingly to WLD; while fen communities were pushed from their initial states to vegetation succession, ombrotrophic communities showed higher inter‐annual variation but stayed within their initial state over the sixteen years following drainage. This pattern found here for peatland vegetation agrees with the general theory first grounded in grasslands and forests (Davis, Grime, & Thompson, ; Eskelinen & Harrison, ; Roberts & Gilliam, ) that mesic communities are more sensitive than nutrient‐poor communities to environmental perturbation.…”

Section: Discussionsupporting

confidence: 90%

Responses of peatland vegetation to 15‐year water level drawdown as mediated by fertility level

Kokkonen

Laine

et al. 2019

J Vegetation Science

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Questions Peatland ecosystems are a globally important carbon storage that is predicted to turn into a carbon source due to water level drawdown (WLD) associated with climate change. The predictions assume stable plant communities but how realistic is this assumption? If the vegetation is not stable, what are the nature and rate of changes? Location Peatland complex in Southern Finland. Methods We conducted a water level drawdown (WLD of ~10 cm) experiment over 17 years in three peatland types differing in their fertility. On each peatland type, we included an adjacent forestry drained (FD, with water table ca. 40 cm lower than in control) area for comparison. Results Peatland type had a clear impact on the response to WLD: at the ecosystem level, the two minerotrophic fens underwent rapid species turnover, while the vegetation in nutrient‐poor bog was more resilient to change. In nutrient‐rich sites, WLD initiated tree canopy development and created understorey conditions that strengthened impact of WLD. In nutrient‐poor site, tree establishment was seen only in the FD area. In addition to high nutrient level, high wetness accelerated change at the plant community level, where we found three types of responses: accelerating change, decelerating change, and stability. Succession resulted in an overall loss of community heterogeneity. Conclusions Interaction between hydrology, nutrient availability, and biological factors in boreal peatlands is important: the drop in water table required to achieve the shift from open peatland to forested system is inversely proportional to the nutrient level of the system. The results suggest that predictive models of peatland functions under climate change should consider compositional change for fens and their diverse plant communities but are more realistic for bogs. The response of bog vegetation to climate change may, however, be more dependent on changes in rainfall regime and therefore needs to be further addressed.

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“…Predicting ecosystem responses to global change is a fundamental issue in ecology. It has been well documented that the aboveground plant community is sensitive to precipitation change (Cleland et al, 2013;Eskelinen and Harrison, 2015) and N deposition (Stevens et al, 2004;Clark and Tilman, 2008), particularly in arid and semi-arid grassland ecosystems, where water and N are generally considered to be limiting resources (Harpole et al, 2007;Yang et al, 2011;Xu et al, 2012b). A growing body of evidence suggests that higher precipitation increases plant species richness (Bai et al, 2008;Xu et al, 2015b), whereas N fertilization is reported as the main driver of the loss of species richness (Gough et al, 2000;Stevens et al, 2004;Yang et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Responses of soil microbial functional genes to global changes are indirectly influenced by aboveground plant biomass variation

Yang

et al. 2017

Soil Biology and Biochemistry

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a b s t r a c tGlobal nitrogen (N) deposition and precipitation change are two important factors influencing the diversity and function of terrestrial ecosystems. While considerable efforts have been devoted to investigate the responses of aboveground plant communities to altered precipitation regimes and N enrichment, the variations of belowground soil microbial communities are not well understood, particularly at the functional gene structure level. Based on a 9-year field experiment established in a typical steppe in Inner Mongolia, China, we examined the impacts of projected N deposition and precipitation increment on soil microbial functional gene composition, and assessed the soil/plant factors associated with the observed impacts. The overall functional gene composition significantly shifted in response to precipitation increment, N deposition and their combinations (all ADONIS P < 0.05), and such changes were primarily correlated with soil pH, microbial biomass, and microbial respiration. Water supply increased the abundances of both carbon (C) and N cycling genes, suggesting that the projected precipitation increment could accelerate nutrient cycling in this semi-arid region. N effects were mainly observed on the genes involved in vanillin/lignin degradations, implying that the recalcitrant C would not accumulate in soil under future scenarios of higher N deposition. Structural equation modeling (SEM) analysis revealed that soil dissolved organic carbon (DOC) was a key factor directly determining the abundance of C degradation and N cycling genes, and aboveground plant biomass indirectly influenced gene abundance through enhancing DOC. The present work provides important insights on the microbial functional feedbacks to projected global change in this semi-arid grassland ecosystem, and the mechanisms governing C and N cycles at the regional scale.

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Resource colimitation governs plant community responses to altered precipitation

Cited by 109 publications

References 63 publications

Nitrogen deposition magnifies the sensitivity of desert steppe plant communities to large changes in precipitation

Nitrogen deposition magnifies the sensitivity of desert steppe plant communities to large changes in precipitation

Responses of peatland vegetation to 15‐year water level drawdown as mediated by fertility level

Responses of soil microbial functional genes to global changes are indirectly influenced by aboveground plant biomass variation

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