Sea lions are highly communal pinnipeds that often congregate in large numbers on coastal rookeries. While this behavior serves a social role, it also has the potential to change the microhabitat and thus the local thermal conditions experienced by the animals. However, the thermal consequences of huddling in pinnipeds have yet to be quantified despite a propensity for close proximity in some species. To investigate
this, we quantified the huddling behavior of California sea lions, Zalophus californianus, by measuring the proximity of individuals from digital photographs, and determined the thermal microhabitat of huddles using an infrared temperature monitor. All animals were measured on San Nicolas Island (California, USA) for 6 days in winter selleck chemical (Tair = 13.2 ± 2.1°C) and 7 days in summer (Tair = 21.1 ± 3.4°C). We found that sea lion huddling behavior increased in colder weather, as determined from three indices.
First, a larger proportion (up to 97%) of the animals participated in huddles rather than resting alone during the winter season (P = 0.010). Second, the number of animals per huddle was larger (reaching 172 animals) during the colder season (P = 0.019). Lastly, sea lions participating in this behavior huddled more tightly in cold temperatures (P = 0.023). The temperature differential between the animals’ skin surface and that of the surrounding substrate was significantly greater (P < 0.001) for huddling sea lions (6.0 ± 3.6°C) KPT-330 chemical structure than for animals resting alone (3.0 ± 2.8°C). Furthermore, this differential was inversely proportional
to ambient temperatures. These results are consistent with huddling behavior in California sea lions providing a significant thermal benefit that likely shapes their social behavior on land. “
“Exploration behaviour is a complex trait that may have strong implications for the fitness of individuals and the persistence of populations. Understanding the different exploration MCE公司 strategies is necessary to understand how animals may adapt to changes in their environment including human-induced habitat fragmentation. Behavioural syndromes are often thought to characterize exploration behaviour, and within a population, individual strategies may vary from ‘bold’ to ‘shy’. Although our understanding of behavioural syndromes has increased enormously over the past decade, little is known about the presence of such syndromes in frogs. Yet, frogs are particularly sensitive to changes in their environment because of their ectothermic physiology and low mobility. Here, we investigate the exploration behaviour of wild-caught male frogs under laboratory conditions to test whether distinct behavioural strategies exist. We demonstrate the presence of different behavioural syndromes with two of the syndromes that can be categorized as ‘bold’ and ‘shy’, and a third one that is clearly intermediate.