Thermoregulation in four species of British grasshoppers (Orthoptera: Acrididae)

1. This study examines the extent to which thermal balance and thermoregulatory ability may contribute to habitat partitioning in insect herbivores.
2. The distribution of four species of grasshopper on a Breckland grass heath is described. Myrmeleotettix maculatus is restricted to short swards, Omocestus viridulus is restricted to long swards, and Chorthippus brunneus and Stenobothrus lineatus are found on swards of intermediate length.
3. Short swards are warmer on average than long swards, but lack cooler refuges on hot days.
4. Chorthippus brunneus and O. viridulus are better able to raise their body temperatures at low ambient temperatures than M. maculatus and S. lineatus . Omocestus viridulus is less able to reduce body temperature at high ambient temperature.
5. Myrmeleotettix maculatus may be precluded from inhabiting cooler long swards because of its inability to raise body temperatures at low ambient temperatures. Omocestus viridulus may avoid short swards because of the danger of overheating.
6. Thermoregulatory ability is a good predictor of the distribution of the grasshoppers in swards of differing length and microclimate.     

Thermal constraints for stingless bee foragers: the importance of body size and coloration

In the dry tropics, foraging bees face significant thermal constraints as a result of high ambient temperatures and direct insolation. In order to determine the potential importance of body size and body coloration in heat gain and heat loss, passive warm-up and cooling rates were measured for freshly killed workers of 24 stingless bee species. Results accorded with biophysical principles. Small bees reached lower temperature excesses (T_exc) and warmed up and lost heat much more rapidly than larger bees. In addition to body size, body coloration had a clear effect on thermal parameters. Light-coloured bees warmed up less rapidly and had lower T_exc than dark bees. An intraspecific comparison of Melipona costaricensis and Cephalotrigona capitata colour morphs confirmed that body coloration influences thermal characteristics. This study is the first to indicate that abdominal coloration in stingless bees might be involved in the regulation of body temperature in extreme thermal conditions. However, body temperatures of foraging bees of colour morphs were not very different. This is probably due to behavioural adaptations (e.g. foraging strategies) or differences in convective and evaporative heat loss or the production of metabolic heat during flight, that all mask the effect of body colour. Notwithstanding such effects and potential thermoregulatory capabilities, stingless bees show niche differentiation and biogeographic distributions that correlate with body coloration and body size. This also suggests that, in general, light bees have an advantage over black bees in hot open lowland habitats, whereas black bees might have an advantage in wet habitats and mountains. The origin, occurrence and function of flavinism (yellow integument colouring) are discussed.     

Some like it hot: body and weapon size affect thermoregulation in horned beetles

Body size and shape affect thermoregulatory properties of organisms, and in turn are believed to have shaped macroevolutionary patterns of morphological diversity across many taxa. However, it is less clear whether thermoregulation plays a role in shaping intraspecific morphological diversity such as sexual dimorphisms or the conditional expression of exaggerated secondary sexual traits. Here, we investigate individual thermoregulatory properties in two species of horned beetles that share similar ecologies and body size ranges, but differ substantially in degree of sexual and male dimorphism. We find that intraspecific variation in body size had an unexpectedly large effect on thermal preference behavior and the ability to passively regulate body temperature. Furthermore, we find that the presence or absence of exaggerated secondary sexual traits dramatically altered thermal preference behavior, consistent with a thermoregulatory cost of horn possession. Lastly, we show that the increase in surface area associated with the expression of enlarged horns is, by itself, insufficient to account for the radically altered thermoregulatory behavior observed in horn-bearing males, and discuss possible alternative, physiological explanations. These findings are among the first to link intra-and interspecific variation in body- and weapon size to thermal preferences within and between insect species.     

Short-term thermoregulatory adjustments in a South American anseriform, the black-necked swan (Cygnus melanocoryphus)

Avian bioenergetic studies suggest that, compared with other vertebrates, birds are efficient thermoregulators. However, most avian physiological studies have been performed in species of small body masses (less than 1 kg). In contrast to what might be anticipated, thermoregulatory abilities of large, flying birds are scarcely studied, especially in temperate zones and aquatic systems. In order to determine short-term metabolic adjustment after thermal challenge, we studied the bioenergetics of a South American anseriform, the black-necked swan (Cygnus melanocoryphus). Our results suggest that this swan species exhibits lower resting metabolic rate compared with other anseriforms, and some hetherothermia. In addition, the black-necked swans in our study changed "wet" thermal conductance at different ambient temperatures. At our working Ta range (5, 10, 15, 20 and 25 degrees C) calculated values were considerably higher than expected (23%, 26%, 39% and 51% higher than expected, respectively). Our results differ considerably from the only two previous reports in swan species, suggesting that C. melanocoryphus, perhaps due to its temperate distribution, is more sensitive to changes in environmental temperature.     

Small bees overheat in sunlit flowers: do they make cooling flights?

1. Although thermoregulation by large bees in cool climates has been well studied, less is known about the very different thermoregulatory strategies of small bees, especially those subjected to heat stress. 2. Studies were carried out on small (< 20 mg fresh weight), dark‐coloured, solitary bees (mostly halictids and hylaeine colletids) experiencing an extreme radiative heat load, enhanced by the high‐altitude location and by reflection of incident radiation by the high‐albedo petals of the flowers of Potentilla lancinata. 3. When foraging in the flowers, such bees experienced peak operative temperatures exceeding 44 °C. In these conditions, males largely stopped foraging but females continued, usually limiting their flower visits to a few seconds and making frequent short flights. These flights would cool the bees down, because bees suspended in air were cooler than bees in sunlit flowers, and convective cooling during flight would further enhance the cooling effect of departure from the flower. 4. As far as is known, cooling flights in small bees have not been proposed before, providing a new avenue for exploration of bee thermoregulatory strategies.     

Body temperature and insulation in diving Great Cormorants and European Shags

1. Cormorants are typically considered as wettable diving birds with high thermoregulatory costs and are presumed to exert substantial predatory pressure on fish stocks.
2. The stomach temperatures of seven Great Cormorants and three European Shags were recorded during a total of 108 foraging trips undertaken near the Chausey Islands breeding colony (France).
3. Both species kept a constant body temperature during the dive series which lasted up to 158 min and were conducted in 12°C water. Consequently, assuming that heat loss to the water is equal to heat production in diving Great Cormorants, the minimal insulating plumage air volume was calculated to be 0·371 × 10^–3 m³ (corresponding to a 1·62-mm air layer) in males and 0·347 × 10^–3 m³ (corresponding to a 1·90-mm air layer) in females.
4. Furthermore, it is shown that plumage air volume and dive depth are the major factors influencing heat flux to the water and that the energetics of diving Great Cormorants may also vary substantially according to fat layer thickness, water temperature and body temperature. Swim speed plays only a minor role.
5. Considering these results, it is postulated that Great Cormorants may have optimized plumage air volume so as to minimize both mechanical costs (upthrust) and thermoregulatory costs of swimming in cold, shallow water.
6. Finally, body temperature patterns recorded in different cormorant species while diving are compared.     

HOBOs, Tidbits and lizard models: the utility of electronic devices in field studies of ectotherm thermoregulation

1. A replicated experiment tested the null hypothesis that stand-alone electronic temperature recording devices produce sets of operative temperatures similar to those produced using lizard models.
2. Commercially available electronic temperature recording devices (HOBO XT™ with external probe and Tidbit™) produced sets of operative temperatures nearly identical to models designed to mimic the size, shape, scale architecture and colour of two species of common North American lizards.
3. Tidbits™ performed better than external probes.
4. These results suggest that electronic devices (especially Tidbits™) can be substituted for models in many applications and that size, morphology, scale architecture and colour contribute very little to temperature change in small-sized life-like models widely used in field-based studies on the thermal ecology of vertebrates.
5. Small differences between temperatures recorded by electronic devices and detailed lizard-shaped models fitted with thermal probes suggest that these models may nevertheless be necessary for certain kinds of studies.     

Patterns of size variation in bees at a continental scale: does Bergmann's rule apply?

Body size latitudinal clines have been widley explained by the Bergmann's rule in homeothermic vertebrates. However, there is no general consensus in poikilotherms organisms in particular in insects that represent the large majority of wildlife. Among them, bees are a highly diverse pollinators group with high economic and ecological value. Nevertheless, no comprehensive studies of species assemblages at a phylogenetically larger scale have been carried out even if they could identify the traits and the ecological conditions that generate different patterns of latitudinal size variation. We aimed to test Bergmann's rule for wild bees by assessing relationships between body size and latitude at continental and community levels. We tested our hypotheses for bees showing different life history traits (i.e. sociality and nesting behaviour). We used 142 008 distribution records of 615 bee species at 50 × 50 km (CGRS) grids across the West Palearctic. We then applied generalized least squares fitted linear model (GLS) to assess the relationship between latitude and mean body size of bees, taking into account spatial autocorrelation. For all bee species grouped, mean body size increased with higher latitudes, and so followed Bergmann's rule. However, considering bee genera separately, four genera were consistent with Bergmann's rule, while three showed a converse trend, and three showed no significant cline. All life history traits used here (i.e. solitary, social and parasitic behaviour; ground and stem nesting behaviour) displayed a Bergmann's cline. In general there is a main trend for larger bees in colder habitats, which is likely to be related to their thermoregulatory abilities and partial endothermy, even if a ‘season length effect’ (i.e. shorter foraging season) is a potential driver of the converse Bergmann's cline particularly in bumblebees.     

Plastic collective endothermy in a complex animal society (army ant bivouacs: Eciton burchellii parvispinum)

Endothermic animals do not always have a single adaptive internal temperature; some species exhibit plastic homeostasis, adaptively allowing body temperature to drop when thermoregulatory costs are high. Like large‐bodied endotherms, some animal societies exhibit collective thermal homeostasis. We tested for plasticity of thermoregulation in the self‐assembled temporary nests (bivouacs) of army ants. We measured core bivouac temperatures under a range of environmental conditions and at different colony developmental (larval vs pupal brood) stages. Contrary to previous assertions, bivouacs were not perfect thermoregulators in all developmental stages. Instead, bivouacs functioned as superorganismal facultative endotherms, using a combination of site choice and context‐dependent metabolic heating to adjust core temperatures across an elevational cline in ambient temperature. When ambient temperature was low, the magnitude of metabolic heating was dependent on colony developmental stage: pupal bivouacs were warmer than larval bivouacs. At cooler high elevations, bivouacs functioned like some endothermic animals that intermittently lower their body temperatures to conserve energy. Bivouacs potentially conserved energy by investing less metabolic heating in larval brood because the high costs of impaired worker development may require more stringent thermoregulation of pupae. Our data also suggest that site choice played an important role in bivouac cooling under high ambient temperatures at low elevations. Climate warming may expand upper elevational range limits of Eciton burchellii parvispinum, while reducing the availability of cool and moist bivouac sites at lower elevations, potentially leading to future low‐elevation range contraction.     

Thermoregulatory responses to manipulations of photoperiod in wood mice Apodemus sylvaticus from high latitudes (57°N)

1. 1. The thermoregulatory responses to manipulations of photoperiod in wood mice (Apodemus sylvaticus), which were drawn from a population living at a high latitude (57°N) were studied.

2. 2. Mice captured in spring were acclimated to two different photoperiod regimes 16L:8D and 8L:16D at a constant ambient temperature of 24°C, for 3 weeks.

3. 3. Daily rhythms of body temperature, oxygen consumption and body temperature at various ambient temperatures, nonshivering thermogenesis (the response to a noradrenaline injection) and body mass were measured. Minimal overall thermal conductance was calculated for both groups.

4. 4. Acclimation to long photophase increased the thermoregulatory abilities at relatively high ambient temperatures while that of long-scotophase increased thermoregulatory abilities at low ambient temperatures.

5. 5. Changes in photoperiod may therefore be used as cues for seasonal acclimatization of thermoregulatory mechanisms in this population of wood mice.