气候变化领域集成服务门户

Understanding the interaction between organisms' life history traits and environmental factors is an essential task in ecology. In spite of the increasing appreciation of jellyfish as an important component in marine ecosystem, there are still considerable gaps in understanding how the phase transition from the benthic polyp to the pelagicmedusa stage is influenced bymultiple environmental factors, including nutrition. To investigate survival, growth, and phase transition of Aurelia aurita polyps, we designed a factorial experiment manipulating food quantity (20 mu g C, 5 mu g C and 1.5 mu g C polyp-1 every other day), food quality (Artemia salina and two dietary manipulated Acartia tonsa), and temperature (13 degrees C, 20 degrees C, and 27 degrees C). Temperaturewas the key factor determining phase transition of polyps and negatively affecting their survival rate and growth at 27 degrees C, which reflected a summer heatwave scenario. Furthermore, at polyps' optimum tolerance temperature (20 degrees C) in our study, budding reproduction benefits from high food concentrations. Interestingly, polyps fed with food containing high level highly unsaturated fatty acid (HUFA) were able to compensate for physiological stress caused by the extreme temperature, and could enhance budding reproduction at optimumtemperature. Moreover, benthic-pelagic coupling (strobilation) was determined by temperature but affected significantly by food conditions. Mild temperature together with optimum food conditions contributes to inducing more polyps, which may potentially bring about great ephyrae recruitments during overwintering. In contrast, heatwave events can potentially regulate plankton community structure accompanied by changes of nutritional conditions of primary and secondary producers and thus, negatively affect the population dynamics of polyps. We suggest a novel polyp tolerance curve, which can help to understand jellyfish population dynamics in different seasons and ecosystems. This sets up a baseline for understanding how anticipated global warming and food conditions may affect the population size of benthic polyps and consequently pelagic medusae. (c) 2018 Elsevier B.V. All rights reserved.