| Title: | DRI-Grass: A New Experimental Platform for Addressing Grassland Ecosystem Responses to Future Precipitation Scenarios in South-East Australia |
| Author(s): | Power SA; Barnett KL; Ochoa-Hueso R; Facey SL; Gibson-Forty EV; Hartley SE; Nielsen UN; Tissue DT; Johnson SN; |
| Address: | "Hawkesbury Institute for the Environment, Western Sydney University, Penrith NSW, Australia. Hawkesbury Institute for the Environment, Western Sydney University, PenrithNSW, Australia; Department of Evolution and Ecology, University of TubingenTubingen, Germany; School of Biosciences, Cardiff UniversityCardiff, UK. Department of Biology, York Environment and Sustainability Institute, University of York York, UK" |
| ISSN/ISBN: | 1664-462X (Print) 1664-462X (Electronic) 1664-462X (Linking) |
| 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 - DRI-Grass (Drought and Root Herbivore Interactions in a Grassland) - that exposes a south-eastern Australian grassland to five rainfall regimes [Ambient (AMB), increased amount (IA, +50%), 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 degrees C day, +0.26 degrees C 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" |
| Keywords: | Npp climate extremes community ecology drought plant-herbivore interactions rainfall manipulation root herbivory; |
| Notes: | "PubMed-not-MEDLINEPower, 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 eng Switzerland 2016/10/06 Front Plant Sci. 2016 Sep 20; 7:1373. doi: 10.3389/fpls.2016.01373. eCollection 2016" |
