Daily Torpor in Birds and Mammals: Past, Present, and Future of the Field.

Torpor is an incredibly efficient energy-saving strategy that many endothermic birds and mammals use to save energy, by lowering their metabolic rates, heart rates, and typically body temperatures. Over the last few decades, the study of daily torpor-in which torpor is used for less than 24 hours per bout-has advanced rapidly. The papers in this issue cover the ecological and evolutionary drivers of torpor, as well as some of the mechanisms governing torpor use. We identified broad focus areas that need special attention: clearly defining the various parameters that indicate torpor use and identifying the genetic and neurological mechanisms regulating torpor. Recent studies on daily torpor and heterothermy, including the ones in this issue, have furthered the field immensely. We look forward to a period of immense growth in this field.

Free-living Allen's hummingbirds (Selasphorus sasin) rarely use torpor while nesting.

For reproducing animals, maintaining energy balance despite thermoregulatory challenges is important for surviving and successfully raising offspring. This is especially apparent in small endotherms that exhibit high mass-specific metabolic rates and live in unpredictable environments. Many of these animals use torpor, substantially reducing their metabolic rate and often body temperature to cope with high energetic demands during non-foraging periods. In birds, when the incubating parent uses torpor, the lowered temperatures that thermally sensitive offspring experience could delay development or increase mortality risk. We used thermal imaging to noninvasively explore how nesting female hummingbirds sustain their own energy balance while effectively incubating their eggs and brooding their chicks. We located 67 active Allen's hummingbird (Selasphorus sasin) nests in Los Angeles, California and recorded nightly time-lapse thermal images at 14 of these nests for 108 nights using thermal cameras. We found that nesting females usually avoided entering torpor, with one bird entering deep torpor on two nights (2% of nights), and two other birds possibly using shallow torpor on three nights (3% of nights). We also modeled nightly energetic requirements of a bird experiencing nest temperatures vs. ambient temperature and using torpor or remaining normothermic, using data from similarly-sized broad-billed hummingbirds. Overall, we suggest that the warm environment of the nest, and possibly shallow torpor, help brooding female hummingbirds reduce their own energy requirements while prioritizing the energetic demands of their offspring.

Reversal of the adipostat control of torpor during migration in hummingbirds.

Many small endotherms use torpor to reduce metabolic rate and manage daily energy balance. However, the physiological 'rules' that govern torpor use are unclear. We tracked torpor use and body composition in ruby-throated hummingbirds (Archilochus colubris), a long-distance migrant, throughout the summer using respirometry and quantitative magnetic resonance. During the mid-summer, birds entered torpor at consistently low fat stores (~5% of body mass), and torpor duration was negatively related to evening fat load. Remarkably, this energy emergency strategy was abandoned in the late summer when birds accumulated fat for migration. During the migration period, birds were more likely to enter torpor on nights when they had higher fat stores, and fat gain was positively correlated with the amount of torpor used. These findings demonstrate the versatility of torpor throughout the annual cycle and suggest a fundamental change in physiological feedback between adiposity and torpor during migration. Moreover, this study highlights the underappreciated importance of facultative heterothermy in migratory ecology.

Torpor is an energy-saving strategy used by warm-blooded animals, including birds and small mammals. Similar to hibernation, although shorter in duration, torpor is a state of minimal activity, low body temperatures and reduced metabolism that helps animals conserve energy in unfavorable conditions. Some animals use torpor to survive times when food is not readily available. Hummingbirds, for example, eat nectar all day long to meet their high energy needs, but must build fat reserves to see them through their overnight fast. If they go to sleep with too little fat, they can descend into torpor to stretch out that limited energy supply and survive until morning. Many hummingbirds migrate to areas with warmer weather, where food remains available, for the winter months. The ruby-throated hummingbird (Archilochus colubris), for example, travels over 5,000 kilometers in its fall migration. Like most long-distance migrants, ruby-throated hummingbirds increase their fat stores before departing, using these stores to fuel their journey. It is thought that this bird may use torpor as a way to accelerate fat build up before its annual migration. However, it remained unclear whether hummingbirds switched from using torpor strictly in energy emergencies, to using it as strategy to prepare for migration. To shed light on this question, Eberts, Guglielmo and Welch investigated when, why and how hummingbirds save energy using torpor during the summer, and whether there are seasonal shifts in their use of torpor coinciding with migration. Eberts, Guglielmo and Welch hypothesized that a bird would initiate daily torpor if its energy stores fall below a critical level during the night, but that they may abandon this threshold (triggering torpor at higher fat levels) in late summer as a way to spare energy and gain fat before their annual migration. To test their hypotheses, Eberts, Guglielmo and Welch tracked body composition, food intake, energy expenditure and torpor use throughout summer in a group of captive ruby-throated hummingbirds. In the middle of the summer, the birds entered torpor and remained torpid for longer when they went to sleep with low fat stores. In late summer, however, the same birds were more likely to enter torpor at consistent times and when they had higher fat stores. Eberts, Guglielmo and Welch also observed that the more time birds spent in torpor, the more fat they gained. This suggests that in late summer, hummingbirds switch from using torpor as a survival strategy to using it to maximize energy savings before migration. These results clearly define the physiological rules governing torpor use in hummingbirds. They also support the long-standing assumption that torpor helps migratory species save energy and accumulate fat stores before long-haul flights.