6 results on '"Nielsen, Uffe N."'
Search Results
2. Ecosystem‐level decoupling in response to reduced precipitation frequency and degradation in steppe grassland.
- Author
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Yang, Tianxue, Zhong, Xiaoyue, Chen, Junda, Nielsen, Uffe N., Ochoa‐Hueso, Raúl, Qu, Yanan, Sui, Yushu, Gao, Weifeng, and Sun, Wei
- Subjects
GRASSLANDS ,GRASSLAND restoration ,ECOLOGICAL impact ,STEPPES ,SOIL moisture ,PLANT biomass - Abstract
Grasslands across arid and semi‐arid regions are predicted to experience reductions in precipitation frequency. Besides, grassland degradation has become a serious problem in many of these areas. Despite increasing evidence suggesting compound effects of these synchronous alterations on biotic and abiotic ecosystem constituents, we still do not know how they will impact the coupling among ecosystem constituents and its consequences on ecosystem functioning.Here, we assessed the effects of decreased precipitation frequency and grassland degradation on ecosystem coupling, quantified based on the mean strength of pairwise correlations among multispecies communities and their physicochemical environment, individual functions and ecosystem multifunctionality, and reported their relationships within a mechanistic plant–nematode–micro‐organism–soil interactions framework.Decreased precipitation frequency led to poorly coupled ecosystems, and reduced aboveground plant biomass, soil water content, soil nutrient levels, soil biota abundance and multifunctionality. By contrast, belowground plant biomass and soil potential enzyme activities increased under decreased precipitation frequency treatment. Severe degradation resulted in decoupled ecosystems and suppressed most of individual functions and multifunctionality. Using structural equation modelling, we showed that coupling had a strong direct positive effect on multifunctionality (standardized total effect: 0.74), while multifunctionality was weakened by greater soil water variation (−0.54) and higher soil pH (−0.53).The great sensitivity of ecosystem coupling to altered precipitation regimes and degradation highlights the importance of considering interactions among biotic and abiotic components when predicting early ecological impacts under changing environments. Moreover, the positive relationship between ecosystem coupling and functioning suggests that restoration of degraded grasslands may be achieved by intensifying ecological interactions. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
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3. DRI-Grass: A New Experimental Platform for Addressing Grassland Ecosystem Responses to Future Precipitation Scenarios in South-East Australia.
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Power, Sally A., Barnett, Kirk L., Ochoa-Hueso, Raul, Facey, Sarah L., Gibson-Forty, Eleanor V. J., Hartley, Susan E., Nielsen, Uffe N., Tissue, David T., Johnson, Scott N., Ahmed, Mukhtar, and Gherardi, Laureano
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ECOLOGY ,GRASSLANDS ,METEOROLOGICAL precipitation ,AGRICULTURAL climatology - Abstract
Climate models predict shifts in the amount, frequency and seasonality of rainfall. Given close links between grassland productivity and rainfall, such changes are likely to have profound effects on the functioning of grassland ecosystems and modify species interactions. Here, we introduce a unique, new experimental platform - DRIGrass (Drought and Root Herbivore Interactions in a Grassland) - that exposes a south-eastern Australian grassland to five rainfall regimes [Ambient (AMB), increased amount (IA, C50%), reduced amount (RA, -50%), reduced frequency (RF, single rainfall event every 21 days, with total amount unchanged) and summer drought (SD, 12-14 weeks without water, December-March)], and contrasting levels of root herbivory. Incorporation of a belowground herbivore (root-feeding scarabs) addition treatment allows novel investigation of ecological responses to the twin stresses of altered rainfall and root herbivory. We quantified effects of permanently installed rain shelters on microclimate by comparison with outside plots, identifying small shelter effects on air temperature (-0.19℃ day, C0.26℃ night), soil water content (SWC; -8%) and photosynthetically active radiation (PAR; -16%). Shelters were associated with modest increases in net primary productivity (NPP), particularly during the cool season. Rainfall treatments generated substantial differences in SWC, with the exception of IA; the latter is likely due to a combination of higher transpiration rates associated with greater plant biomass in IA and the low water-holding capacity of the well-drained, sandy soil. Growing season NPP was strongly reduced by SD, but did not respond to the other rainfall treatments. Addition of root herbivores did not affect plant biomass and there were no interactions between herbivory and rainfall treatments in the 1st year of study. Root herbivory did, however, induce foliar silicon-based defenses in Cynodon dactylon and Eragrostis curvula. Rapid recovery of NPP following resumption of watering in SD plots indicates high functional resilience at the site, and may reflect adaptation of the vegetation to historically high variability in rainfall, both within- and between years. DRI-Grass provides a unique platform for understanding how ecological interactions will be affected by changing rainfall regimes and, specifically, how belowground herbivory modifies grassland resistance and resilience to climate extremes. [ABSTRACT FROM AUTHOR]
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- 2016
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4. Prolonged drought causes negative plant-soil feedbacks in grassland species under field conditions.
- Author
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Hassan, Kamrul, Carrillo, Yolima, and Nielsen, Uffe N.
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DROUGHTS , *GRASSLAND soils , *COEXISTENCE of species , *PLANT nematodes , *VESICULAR-arbuscular mycorrhizas , *PLANT competition , *GRASSLANDS - Abstract
Climate change has been shown to alter plant-soil feedbacks (PSFs, the impacts of plants on future communities via their impacts on soil biotic and abiotic properties), with implications for plant community dynamics. However, few studies have assessed effects on PSFs under field conditions or the mechanisms involved. We assessed drought effects on PSFs of four common grassland species (Lolium multiflorum, Medicago sativa , Plantago lanceolata, and Trifolium repens) in situ in a mesic grassland under ambient rainfall and prolonged drought conditions using a long-term rainfall manipulation system. The four species were first grown in monocultures in sub-plots of each of six ambient and drought plots to condition the soils. Then, each species was grown in a sub-plot conditioned by the same species ('home') and a sub-plot conditioned by each of the other three species ('away'). We found that three species (L. multiflorum, M. sativa and T. repens) produced higher biomass in their 'home' soil than away soil under ambient rainfall while they consistently grew better in away soil under drought conditions, indicating drought-induced negative shifts in PSFs. There were strong interaction effects of rainfall treatment and conditioning species on several phospholipid-derived fatty acids markers, including a marker associated with arbuscular mycorrhizal fungi (AMF). We found a significant positive correlation between PSFs and the AMF marker across all treatment combinations, indicating that PSFs were driven by changes in positive plant-soil biotic interactions. Furthermore, drought increased plant parasitic nematode abundances. We found a strong significant negative correlation between PSFs and plant parasitic nematodes across all treatment combinations, indicating that the drought-induced shifts to more negative PSFs were driven by increased negative plant-soil biotic interactions. Drought may therefore negatively impact common grassland species due to stronger negative PSFs but at the same time promote species co-existence by reducing the abundance of competitive species. • Drought induces negative PSFs in four common grassland plant species. • Negative PSFs were associated with greater root feeding nematode densities under drought. • PSF effect sizes were also correlated with indicators of beneficial plant-soil biotic interactions across all treatments. • Prolonged drought may promote species co-existence due to reduced plant competition. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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5. Phosphorus addition ameliorates soil micro-food web simplification due to nitrogen enrichment but does not restore nematode community composition.
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Ma, Bing, Sheng, Xiongjie, Zhou, Juan, Nielsen, Uffe N., Wang, Xiangtai, and Ma, Miaojun
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PLATEAUS , *GRASSLAND restoration , *MOUNTAIN meadows , *STRUCTURAL equation modeling , *PLANT diversity , *SOILS , *GRASSLANDS , *ECOSYSTEMS - Abstract
Nitrogen (N) inputs to terrestrial ecosystems are increasing faster than phosphorus (P) inputs, causing N:P imbalances and substantial changes in the diversity and structure of plant, soil microbial, and fauna communities. The responses of the soil micro-food web to N:P imbalances remain unclear but are crucial to understanding the impacts on ecosystem functioning. We investigated the effect of N and P additions on plant communities, edaphic properties, and nematode species diversity and composition, and assessed shifts in soil micro-food web complexity using nematode-based indices and structural equation modeling (SEM) in a nine-year nutrient addition experiment in an alpine meadow on the Tibetan Plateau. We found that N addition decreased the structure index (SI) and enrichment index (EI), indicating that N enrichment led to a simplification of the soil micro-food web. The addition of P alleviated the negative effect of N on soil micro-food web complexity but did not restore nematode community composition. The SEM supported the hypothesis that N addition simplified soil micro-food webs through increases in the N:P ratio and associated reductions in plant species richness, while P addition ameliorated the effect of N by decreasing the soil N:P ratio and increasing plant species richness. Our results highlight the positive effects of plant diversity in maintaining the complexity of the soil micro-food web. Our findings provide information that can be used to guide sustainable management and restoration of grasslands to alleviate the projected effects of future N:P imbalances on the soil micro-food web. However, efforts should be made to avoid nutrient deposition given the observed effects on both plant and nematode communities that could not be restored by alleviating the N:P imbalance through P addition. • Phosphorus alleviates soil micro-food web simplification caused by excess nitrogen. • Nematode community composition remains unrestored despite phosphorus addition. • Plant diversity is crucial for maintaining complex soil micro-food webs. • Modifying nitrogen/phosphorus ratio alone can't fully restore communities. [ABSTRACT FROM AUTHOR]
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- 2024
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6. Nematode communities response to long-term grazing disturbance on Tibetan plateau.
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Hu, Jing, Wu, Jihua, Ma, Miaojun, Nielsen, Uffe N., Wang, Jing, and Du, Guozhen
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NEMATODE genetics , *HERBIVORES , *ECOLOGY , *GRASSLANDS , *SOIL animals , *BIODIVERSITY , *MOUNTAIN meadows - Abstract
Grazing by herbivores plays a key role in grassland ecosystems, but its effects on soil fauna biodiversity are not clear in alpine meadow ecosystems, especially on the Tibetan plateau. We investigated the effects of long-term grazing disturbance of varying intensities (low disturbed site, medially disturbed site, and seriously disturbed site) on ecosystem biodiversity and functional process using soil nematode communities. Soil physicochemical characteristics and plant communities were also measured to explore the relationships between soil nematode communities structure and key environment variable. Soil samples were collected in May, June, August, and October, 2013. The abundance of total nematode communities, plant feeders and bacterivores increased with the grazing intensity increase, and predators decreased with grazing intensity increase. Low disturbed site has the lowest abundance of fungivores. Grazing disturbance has no significant influence on abundance of omnivores ( P > 0.05). Species richness was highest on seriously disturbed site and lowest on low disturbed site. MI and SI decreased as grazing intensity increase. The highest NCR was found in low disturbed site and the lowest in medially disturbed site. The highest EI was found in medially disturbed site and the lowest in low disturbed site. Principal component analysis (PCA) showed that nematode communities could be separated by three different grazing disturbance intensity sites. Redundancy analysis (RDA) showed that Helicotylenchus , Acrobeloides and Labronema were positively correlated with higher plant communities diversity. Filenchus was positively correlated with forbs biomass. Some omnivores such as Eudorylaimus and Aporcelaimus was positively correlated with soil moisture and rich nutrient resources, meanwhile, Enchodelus and Coomansus was positively correlated with biomass of sedges and grasses. Anaplectus and Prismatolaimus significantly correlated with soil moisture, nutrient resources and biomass of sedges and grasses. This study revealed that grazing herbivores can change composition, structure and diversity of soil nematode communities, and then reflect radical shift in below-ground soil faunal biodiversity and processes in alpine meadow on the Tibetan plateau. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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