AI Article Synopsis
- The study measured oxygen consumption, body temperature, and wet thermal conductance in three related South American marsupials under different conditions: resting, low temperature, and exercise.
- Despite expectations, Caluromys philander did not show a significantly lower maximal sustained oxygen consumption compared to the other two species, Philander opossum and Metachirus nudicaudatus.
- In cold temperatures, Metachirus nudicaudatus did not survive, while Caluromys philander and Philander opossum were able to lower their body temperature, with C. philander showing gradual decreases and P. opossum only showing significant drops after longer exposure.
Article Abstract
Oxygen consumption (VO(2)), body temperature (T(b)) and wet thermal conductance (C(wet)), under resting conditions, exposure to low ambient temperature (T(a)) and during sustained exercise (treadmill running) were measured in three phylogenetic related (same family; Didelphidae) South American marsupials possessing similar body masses: Caluromys philander (arboreal/fruit and insect eating), Philander opossum (terrestrial and arboreal/omnivore), and Metachirus nudicaudatus (terrestrial/omnivore). Our measurements of VO(2) and C(wet) under resting conditions agree with those previously reported for other marsupials. We expected that C. philander would show a lower maximal sustained VO(2), compared to the other two species, based on its more reduced skeletal muscle mass. However, the values obtained for C. philander were not statistically different (ANOVA) from those obtained for the other two species. When exposed to low ambient temperature (12 degrees C), differences among the three species were detected, i.e., M. nudicaudatus did not survive, while the other two species were able to reduce their T(b) under such conditions. C. philander gradually decreases its T(b) when cold exposed, and P. opossum shows a more pronounced T(b) drop only when exposure to low ambient temperatures occurs for a more prolonged period of time.
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| http://dx.doi.org/10.1016/j.cbpa.2006.08.024 | DOI Listing |
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