Timing of parental breeding shapes sensitivity to nitrate pollution in the common frog Rana temporaria

Abstract

Climate change is expected to increase mean temperatures and the frequency of extreme weather events, that can lead to earlier/extended breeding seasons in temperate taxa. As a consequence, many organisms that show climate-induced phenological shifts might be exposed to environmental conditions they are not well adapted to while breeding, and their ability to cope with stressful conditions might be influenced. Here, we investigated how parental breeding time shapes the sensitivity to nitrate exposure at three consecutive life stages (embryonic, larval, juvenile) in the European common frog (Rana temporaria). We compared hatching success and life-stage specific survival, growth, standard metabolic rate, body condition, and acute thermal sensitivity of offspring from an earlier-breeding parental cohort (early cohort) vs. a later-breeding parental cohort (late cohort) exposed to a range of environmentally relevant concentrations of nitrate (0–100 mg/L). We also investigated whether nitrate exposure experienced during the embryonic and larval stages affects physiological performance in later life stages (after metamorphosis). Our study reveals that parental breeding time affects the sensitivity to nitrate pollution at three consecutive life stages in Rana temporaria. Breeding later in spring reduced hatching size and survival at high nitrate exposure, but also induced compensatory growth of the offspring. In both early and late cohorts, exposure to nitrate pollution reduced developmental rate and led to larger, but older larvae at the onset of metamorphosis with a greater sensitivity to warmer environmental temperatures. Standard metabolic rate, on the contrary, was neither affected by parental breeding time nor by exposure to nitrate. Exposure to nitrate pollution during embryonic and larval development led to carry-over in juvenile froglets as their sensitivity to temperature was higher. In a world highly impacted by humans, it is thus essential to give stressors a more holistic approach in order to better predict their consequences on species subjected to them.