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Disruption of the oak tree microbiome with urbanization

Urbanization disrupts oak tree microbiomes by reducing beneficial fungi and increasing plant and human pathogens across leaves, roots and soils, with consequences for tree health, urban climate mitigation and potential human exposure to pathogens.

Kathryn F. Atherton
Chikae Tatsumi
Jennifer M. Bhatnagar
Research03 Oct 2025
Nature Cities

Volume: 2, P: 958-968
Reply to: Data do not support large-scale oligotrophication of terrestrial ecosystems

Joseph M. Craine
Andrew J. Elmore
Christiane Werner
Research22 Jul 2019
Nature Ecology & Evolution

Volume: 3, P: 1287-1288
Limits on carbon uptake by plants

Increased concentrations of carbon dioxide in the atmosphere support greater plant biomass in grasslands, but this response is constrained in the long term by soil nitrogen availability.

Pamela H. Templer
News & Views26 Feb 2013
Nature Climate Change

Volume: 3, P: 184-185
A meta-analysis of 1,119 manipulative experiments on terrestrial carbon-cycling responses to global change

A synthesis of global change experiments that manipulated temperature, precipitation, carbon dioxide or nitrogen identifies a need to consider site-specific factors and interactions in Earth system models.

Jian Song
Shiqiang Wan
Mengmei Zheng
Research19 Aug 2019
Nature Ecology & Evolution

Volume: 3, P: 1309-1320
Mechanisms for retention of bioavailable nitrogen in volcanic rainforest soils

Pristine temperate rainforests are known to produce large amounts of bioavailable nitrogen, with only minimal loss. Tracing ¹⁵N in volcanic soils of a temperate evergreen rainforest in southern Chile helps to further unravel the retention mechanisms for bioavailable nitrogen in these ecosystems.

Dries Huygens
Pascal Boeckx
Roberto Godoy
Research11 Jul 2008
Nature Geoscience

Volume: 1, P: 543-548
Isotopic evidence for oligotrophication of terrestrial ecosystems

Foliar nitrogen (N) concentrations and isotope ratios obtained from >43,000 samples acquired over 37 years suggest global declines in N supply relative to plant demand, consistent with elevated atmospheric carbon dioxide.

Joseph M. Craine
Andrew J. Elmore
Katarzyna Zmudczyńska-Skarbek
Research22 Oct 2018
Nature Ecology & Evolution

Volume: 2, P: 1735-1744
Increasing soil respiration in a northern hardwood forest indicates symptoms of a changing carbon cycle

Soil respiration rates have almost doubled between 2015-2020 with increased heterotrophic microbial carbon mineralization and microbial biomass, suggesting an increase in the bioavailability of organic carbon, according to an analysis of long-term data from the Hubbard Brook Experimental Forest, U.S.

Angela R. Possinger
Charles T. Driscoll
Peter M. Groffman
ResearchOpen Access29 May 2025
Communications Earth & Environment

Volume: 6, P: 1-11

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Disruption of the oak tree microbiome with urbanization

Reply to: Data do not support large-scale oligotrophication of terrestrial ecosystems

Limits on carbon uptake by plants

A meta-analysis of 1,119 manipulative experiments on terrestrial carbon-cycling responses to global change

Mechanisms for retention of bioavailable nitrogen in volcanic rainforest soils

Isotopic evidence for oligotrophication of terrestrial ecosystems

Increasing soil respiration in a northern hardwood forest indicates symptoms of a changing carbon cycle

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