Post-drought compensatory growth in perennial grasslands is determined by legacy effects of the soil and not by plants

Abstract

Grasslands recovering from drought have repeatedly been shown to outperform non-drought-stressed grasslands in biomass production. The mechanisms that lead to the unexpectedly 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 (DRW_p ) compared with control plants (Ctr_p ) when decoupled from soil-mediated DRW effects, with DRW_p showing less aboveground productivity (-13%), restricted N nutrition, and higher δ¹³ C compared with Ctr_p . However, plants grown on formerly drought-stressed soil (DRW_s ) showed enhanced aboveground productivity (+82%), improved N nutrition, and higher δ¹³ C values relative to plants grown on control soil (Ctr_s ), irrespective of the plants' pretreatment. Our study shows that the higher post-drought productivity of perennial grasslands recovering 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.

Keywords: compensatory growth; drought; grassland; nitrogen; recovery; rewetting.