Cleaning up after a meal: the consequences of prey disposal for pit-building antlion larvae

Predators use a variety of strategies for capturing prey. Trap-building predators can save on searching and encountering costs by investing in the construction and maintenance of traps such as webs and pits. However, what to do with partially consumed prey poses a potential problem. Antlion larvae (Myrmeleon acer) catch ants in conical pits, and dispose of partially consumed carcasses by flicking them a short distance away. We tested whether this prey-disposal behaviour affects the effectiveness of antlion pits. We observed ant behaviour around artificially constructed pits and compared falls into pits with clean margins to those with conspecific ant carcasses or control objects around the pit edge. The presence of objects near pits affected the behaviour of live ants, and reduced the effectiveness of pits. Live ants spent the most time examining fresh ant carcasses, but the presence of any object near pits deterred pitfalls. Ants fell into pits significantly more often when pit edges were clean, suggesting that antlions could incur a prey capture cost from flicking carcasses from pits as well as from the accumulation of other debris around pit margins

Mechanisms of temperature-dependent swimming: the importance of physics, physiology and body size in determining protist swimming speed

Body temperatures and thus physiological rates of poikilothermic organisms are determined by environmental temperature. The power an organism has available for swimming is largely dependent on physiological rates and thus body temperature. However, retarding forces such as drag are contingent on the temperature-dependent physical properties of water and on an organism’s size. Consequently, the swimming ability of poikilotherms is highly temperature dependent. The importance of the temperaturedependent physical properties of water (e.g. viscosity) in determining swimming speed is poorly understood. Here we propose a semi-mechanistic model to describe how biological rates, size and the physics of the environment contribute to the temperature dependency of microbial swimming speed. Data on the swimming speed and size of a predatory protist and its protist prey were collected and used to test our model. Data were collected by manipulating both the temperature and the viscosity (independently of temperature) of the organism’s environment. Protists were either cultured in their test environment (for several generations) or rapidly exposed to their test environment to assess their ability to adapt or acclimate to treatments. Both biological rates and the physics of the environment were predicted to and observed to contribute to the swimming speed of protists. Body size was not temperature dependent, and protists expressed some ability to acclimate to changes in either temperature or viscosity. Overall, using our parameter estimates and novel model, we are able to suggest that 30 to 40% (depending on species) of the response in swimming speed associated with a reduction in temperature from 20 to 5°C is due to viscosity. Because encounter rates between protist predators and their prey are determined by swimming speed, temperature- and viscosity-dependent swimming speeds are likely to result in temperature- and viscosity-dependent trophic interactions

Motility of Daphnia spinulata as Affected by Solar Radiation Throughout an Annual Cycle in Mid-latitudes of Patagonia

During an annual cycle, Daphnia spinulata collected from a plankton community of Patagonia was exposed outdoors to assess the impact of recently received solar radiation on motility (i.e. swimming speed and gravitaxis). Individual values of these parameters were obtained by video recordings and image analysis at different time intervals during the day. Initial swimming speed varied throughout the year, and changes in speed during exposure were not significantly affected by any waveband used in our experimental design (i.e. PAB, 280-700 nm; PA, 320–700 nm; and P, 400–700 nm). Overall, most of the individuals swam downwards, regardless of the radiation treatment imposed to the samples. We found that multifactor interactions (i.e. not a single parameter explained more than 40% of the observed variability) explained most of our observations on motility parameters. These factors include not only solar radiation, but other physical (underwater radiation field and wind intensity) and biological parameters (food availability, presence of predators and congeners). Our findings indicate that the plankton dynamics in the study site is likely to be governed by a sum of factors which must be taken into account when considering solar radiation effects on aquatic ecosystems.Fil: Gonçalves, Rodrigo Javier. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Fundación Playa Unión. Estación de Fotobiología Playa Unión; ArgentinaFil: Barbieri, Elena Susana. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Fundación Playa Unión. Estación de Fotobiología Playa Unión; ArgentinaFil: Villafañe, Virginia Estela. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Fundación Playa Unión. Estación de Fotobiología Playa Unión; ArgentinaFil: Helbling, Eduardo Walter. Fundación Playa Unión. Estación de Fotobiología Playa Unión; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentin