Differing photosynthetic responses to excess irradiance in the two coexisting seagrasses, Halophila ovalis and Halophila decipiens: Chloroplast avoidance movement, chlorophyll fluorescence, and leaf optical properties

Abstract

Seagrasses cope with excess irradiance using a suit of photoprotective mechanisms, however, Halophila species are the only seagrasses known to exhibit chloroplast avoidance movement. Here we examined this phenomenon together with concurrent change in photosynthetic and leaf optical properties in H. ovalis and H. decipiens. Although co-existing, these two seagrasses displayed different light use characteristics derived from rapid light curves; H. ovalis and H. decipiens showed features of sun- and shade-adapted plants, respectively. Experimentally the seagrass leaves were exposed to low, medium, and high irradiance (80, 200 and 800 μmol photons m−2 s−1, respectively) for 60 min, followed by 60 min in darkness. Chloroplast movement occurred in H. ovalis exposed to medium or high irradiance and in H. decipiens exposed to low or medium irradiance. Chloroplast gathering was observed after 20 min of exposure and chloroplast dispersal was observed after 20 min in darkness, dependent on treatment and species. Increasing irradiance lowered the effective quantum yield and increased the non-photochemical quenching (NPQ). Despite stronger up-regulation in NPQ, photoinhibition was detected in H. decipiens. The absorption factor and the Soil-Plant Analysis Development value were modulated by chloroplast movement rather than a change in chlorophyll content, except for H. decipiens exposed to high irradiance where photodamage of chlorophylls may have occurred. Chloroplast movement in both seagrasses was inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea, indicating regulation by photosynthesis. Our results suggest that H. ovalis has a higher tolerance to excess irradiance than H. decipiens and that this is assisted partly by chloroplast avoidance movement.