Post-drought compensatory growth in perennial grasslands is determined by legacy effects of the soil and not by plants
Scharer, M. L., A. Luscher and A. Kahmen. 2023.
Abstract
Grasslands recovering from drought have repeatedly been shown to outperform non�drought-stressed grasslands in biomass production. The mechanisms that lead to the unex�pectedly high biomass production in grasslands recovering from drought are, however, not
understood.
� To disentangle plant-intrinsic and plant-extrinsic (soil) drought legacy effects on grassland
recovery from drought, we designed a factorial field experiment where Lolium perenne plants
that were exposed to either a 2-month drought or to well-watered control conditions were
transplanted into control and drought-stressed soil and rewetted thereafter.
� Drought and rewetting (DRW) resulted in negative drought legacy effects of formerly
drought-stressed plants (DRWp) compared with control plants (Ctrp) when decoupled from
soil-mediated DRW effects, with DRWp showing less aboveground productivity (�13%),
restricted N nutrition, and higher d13C compared with Ctrp. However, plants grown on for�merly drought-stressed soil (DRWs) showed enhanced aboveground productivity ( 82%),
improved N nutrition, and higher d13C values relative to plants grown on control soil (Ctrs),
irrespective of the plants%u2019 pretreatment.
� Our study shows that the higher post-drought productivity of perennial grasslands recover�ing from drought relative to non-drought-stressed controls is induced by soil-mediated DRW
legacy effects which improve plant N nutrition and photosynthetic capacity and that these
effects countervail negative plant-intrinsic drought legacy effects.
Key Words
compensatory growth, drought, grassland, nitrogen, recovery, rewetting
