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Full-Text Articles in Life Sciences
Culturable Root Endophyte Communities Are Shaped By Both Warming And Plant Host Identity In The Rocky Mountains, Usa, Kelly G. Lyons, M. Mann, Molly Lenihan, Olivia Roybal, Kelly Carroll, Kyle Reynoso, S. N. Kivlin, D. L. Taylor, J. A. Rudgers
Culturable Root Endophyte Communities Are Shaped By Both Warming And Plant Host Identity In The Rocky Mountains, Usa, Kelly G. Lyons, M. Mann, Molly Lenihan, Olivia Roybal, Kelly Carroll, Kyle Reynoso, S. N. Kivlin, D. L. Taylor, J. A. Rudgers
Biology Faculty Research
Understanding the biogeographic patterns of root-associated fungi and their sensitivity to temperature may improve predictions of future changes in terrestrial biodiversity and associated ecosystem processes, but data are currently limited. Anticipating change will require combining observational data, which predict how climatic factors limit current species distributions, with direct manipulations of climate, which can isolate responses to specific climate variables. Root endophytes are common symbionts of plants, particularly in arctic and alpine environments, yet their responses to climate warming are not resolved. Here, we directly cultured endophytic fungi from roots collected along altitudinal gradients in replicated mountain watersheds and from a …
Main And Interactive Effects Of Increased Precipitation And Nitrogen Addition On Growth, Morphology, And Nutrition Of Cinnamomum Burmanni Seedlings In A Tropical Forest, Jun Wang, Dafeng Hui, Hongfang Lu, Faming Wang, Nan Liu, Zhongyu Sun, Hai Ren
Main And Interactive Effects Of Increased Precipitation And Nitrogen Addition On Growth, Morphology, And Nutrition Of Cinnamomum Burmanni Seedlings In A Tropical Forest, Jun Wang, Dafeng Hui, Hongfang Lu, Faming Wang, Nan Liu, Zhongyu Sun, Hai Ren
Biology Faculty Research
Global change such as altered precipitation patterns and increased atmospheric nitrogen (N) deposition will have significant impacts on seedling growth during plant recruitment. However, how interactive effects of increased precipitation and N deposition on forest seedling performance have not been well investigated. In this study, we conducted a two-year field experiment that manipulating precipitation amount (ambient rainfall and 25% increment during the wet season) and exogenous N addition (0 and 100 kg ha−1 yr−1) in a tropical secondary forest. Seedling growth, morphology and nutritional status of a dominant tree species (Cinnamomum burmanni) were measured. Results showed that increased precipitation had …
Changing Rainfall Frequency Rather Than Drought Rapidly Alters Annual Soil Respiration In A Tropical Forest, Qi Deng, Deqiang Zhang, Xi Han, Guowei Chu, Quanfa Zhang, Dafeng Hui
Changing Rainfall Frequency Rather Than Drought Rapidly Alters Annual Soil Respiration In A Tropical Forest, Qi Deng, Deqiang Zhang, Xi Han, Guowei Chu, Quanfa Zhang, Dafeng Hui
Biology Faculty Research
Tropical forests play an important role in global carbon (C) cycling due to high primary productivity and rapid litter and soil organic C decomposition. However, it is still unclear how changing rainfall will influence soil CO2 losses (i.e. via soil respiration) in tropical forests. Here, using a rainfall and litter manipulation experiment in a tropical forest, we show that enhanced litter-leached dissolved organic carbon (DOC) production with increased rainfall frequency drives substantial CO2 loss via soil respiration. A 50% increase in rainfall frequency (no change in total rainfall amount) enhanced inputs of DOC by 28%, total dissolved nitrogen (TDN) by …
Projecting Terrestrial Carbon Sequestration Of The Southeastern United States In The 21st Century, Xia Song, Hanqin Tian, Xiaofeng Xu, Dafeng Hui, Guangsheng Chen, Greg Sommers, Luke Marzen, Mingliang Liu
Projecting Terrestrial Carbon Sequestration Of The Southeastern United States In The 21st Century, Xia Song, Hanqin Tian, Xiaofeng Xu, Dafeng Hui, Guangsheng Chen, Greg Sommers, Luke Marzen, Mingliang Liu
Biology Faculty Research
How terrestrial ecosystems respond to future environmental change in the 21st century is critically important for understanding the feedbacks of terrestrial ecosystems to global climate change. The southeastern United States (SEUS) has been one of the major regions acting as a carbon sink over the past century; yet it is unclear how its terrestrial ecosystems will respond to global environmental change in the 21st century. Applying a process-based ecosystem model (Dynamic Land Ecosystem Model, DLEM) in combination with three projected climate change scenarios (A1B, A2, and B1 from the IPCC report) and changes in atmospheric carbon dioxide, nitrogen deposition, and …