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First published online October 18, 2006
Journal of Experimental Biology 209, 4185-4192 (2006)
Published by The Company of Biologists 2006
doi: 10.1242/jeb.02528
Hot bumble bees at good food: thoracic temperature of feeding Bombus wilmattae foragers is tuned to sugar concentration
1 University of California, San Diego, Division of Biological Sciences,
Section of Ecology, Behavior and Evolution, Gilman Drive, La Jolla, CA
92093-0116, USA
2 El Colegio de la Frontera Sur, Tapachula, Chiapas, Mexico
3 University of Illinois, Department of Entomology, 320 Morrill Hall, 505 S.
Goodwin Avenue, Urbana, IL 61801, USA
* Author for correspondence (e-mail: jnieh{at}ucsd.edu)
Accepted 6 September 2006
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Tth (P<0.0001) with
increasing sucrose concentration, with significant differences
(P<0.0001) between colonies due to different linear regression
slopes (0.28-2.4) and y-intercepts (2.7-5.5). We suggest that this
modulation of pitching Tth to sucrose concentration is a
general phenomenon in all social bees and may be a widespread adaptation
facilitating rapid food collection in flying Hymenoptera.
Key words: thermoregulation, foraging, food quality, endothermy, Bombus
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), particularly
in the Hymenoptera (Himmer,
1932). Researchers have reported thermoregulation in ants
(Hölldobler and Wilson,
1990), wasps (Stabentheiner et
al., 2004), solitary bees [Anthophora
(Stone, 1994)] and social bees
(Bujok et al., 2002;
Dyer and Seeley, 1987;
Kleinhenz et al., 2003;
Stabentheiner et al., 1990;
Stone and Willmer, 1989).
Here, we focus on the phenomenon of thoracic metabolic heat production linked
to food quality.
Flight thermoregulation is widely found among bees
(Stone and Willmer, 1989),
including solitary bees [Xylocopa virginica
(Baird, 1986)]. All bees in
which thermoregulation has been examined are heterotherms
(Heinrich, 1993) and can
regulate higher body temperatures during foraging and attacks
(Heinrich, 1979).
Thermoregulation plays a role in the ability of bees to fly
(Coelho, 1991;
Esch, 1976) and thus to visit
flowers under cold conditions (Corbet et
al., 1993). Bombus terrestris, B. pascuorum and B.
hortorum began foraging at lower temperatures than honey bees and were
thus expected to forage earlier in the morning and later in the afternoon than
honey bees (Corbet et al.,
1993), a potential example of how thermoregulation allows niche
specialization. Recently, bumble bees (B. terrestris) have also been
shown to be able to associate warmth with floral color, preferring to visit
warmer flowers in a flight arena (Dyer et
al., 2006).
Several species of honey bees, including Apis mellifera, A. cerana, A.
dorsata and A. laboriosa, are able to regulate their body
temperature, exhibiting higher thoracic temperatures after feeding at rich
sucrose solutions than at poorer sucrose solutions
(Schmaranzer and Stabentheiner,
1988; Underwood,
1991). In general, honey bee thoracic temperature corresponds to
the quality of the food source as perceived by sweetness
(Stabentheiner and Hagmüller,
1991), proximity to the nest
(Esch, 1960;
Stabentheiner, 1996) and
nectar flow rate (Farina and Wainselboim,
2001), with increasing net caloric intake per unit time giving
rise to higher temperatures. In honey bees, metabolic expenditure increases
with increasing nectar flow rate at an artificial feeder
(Balderrama et al., 1992;
Moffatt and Nunez, 1997). On a
feeder, honey bees evidently traded off the amount of energy expended in
keeping the thorax warm and thus in a state of immediate readiness for takeoff
(Moffatt, 2001)
versus net caloric benefits to the colony by expending less energy in
thoracic heating for poorer food
(Waddington, 1990). Honey bees
are thus able to adjust their energetic expenditure and exploit relatively
poor food when richer food is not readily available.
Recently, foragers of the stingless bee Melipona panamica
(Meliponini) also have been shown to adjust their thoracic temperature
according to food caloric value. Like honey bees, M. panamica
foragers maintained a thoracic temperature Tth excess
above air temperature Ta (21.5-29.5°C) that
corresponded to sucrose concentration when unloading food and recruiting
nestmates inside the nest (Nieh and
Sánchez, 2005). Thus the phenomenon of increasing thoracic
temperature with increasing sucrose concentration may be common among the
flying Hymenoptera.
Bumble bees
In their study of bumble bee field foraging, Heinrich and Heinrich observed
an interesting phenomenon in B. vagans, B. terricola and B.
perplexus foragers and wrote: (p. 561) "flight activity by
itself cannot account for the high Tth (>34°C) observed on
raspberry, since bees often perched on flowers and resumed flight fully
heated; they maintained an elevated Tth even while they were
perched" (Heinrich and
Heinrich, 1983b). Based upon recent findings that stingless bee
foragers (Meliponini, Melipona panamica) can maintain elevated
Tth temperatures tuned to food caloric concentration while
feeding (Nieh and Sánchez,
2005), and given that honey bees (Apini) do the same
(Stabentheiner, 2001;
Stabentheiner and Hagmüller,
1991), we examined whether their close relatives, the bumble bees
(Bombini), possess a similar ability.
Bombus wilmattae (Cockerell,
1912) is restricted in distribution to the highlands of Chiapas
and Guatemala, corresponding to that of the Bosque de Pino y Encino and the
Bosque Tropical Caducifolio (Labougle,
1990; Rzedowski,
1978). Elevational distribution of this species, based upon this
and additional studies in preparation (21 additional colonies, R.V.,
unpublished) is between 1413 m and 2014 m. This is considered a
tropical-to-subtropical species, which makes our study particularly
interesting because examinations of bumble bee thoracic temperature have
largely been restricted to temperate species.
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) around the
towns of Unión Juárez, Talquian, and San José, in
Chiapas, Mexico at altitudes ranging from 1110 to 1690 m (laboratory
designations: BW5, BW8, BW10, BW12, BW13 and BW14). We used BW5 from November
to December 2003 and other colonies from August to September 2005. Colonies
were transferred to wood observation hives (30 cm x30 cm x30 cm
for colony BW5 and 18 cm x18 cm x18 cm for all other colonies)
covered with glass. Experiments were conducted inside a laboratory at El
Colegio de la Frontera Sur, Tapachula, Chiapas, Mexico (14°53.191
'N, 92°17.183 'W) inside wood foraging arenas (120 cm
x90 cm x30 cm, L xW xH) covered with IR transparent
plastic film [BCU Plastics, Polyolefin FDA grade 75 gauge film, catalog
#LS-2475, protocol of Stabentheiner and Hagmüller
(Stabentheiner and Hagmüller,
1991)]. Each colony was connected to a single, separate foraging
arena through a 3.5 cm diameter, 10 cm long, clear vinyl tube. All colonies
were maintained inside the laboratory for at least 20 days before use in the
experiments and provided ad libitum with 50% (v/v) honey/water. All
trials were conducted inside a light and temperature-controlled room
(24.4±1.9°C). We visually inspected the exposed honey pots of each
colony before using them in experiments and found that the food stores (honey
and pollen) of all colonies were similar.
Feeders and censusing
Before beginning our experiments, we used paired feeders for a preliminary
test of any potential sucrose concentration effect, and a resulting
thermographic image is shown to better illustrate the effect of sucrose
concentration on forager body temperatures. In our experiments, we measured
the temperatures of bees foraging at a single feeder containing unscented 0.5,
1.0, 1.5, 2.0 or 2.5 mol l-1 sucrose solutions (double distilled
water and reagent grade sucrose, Quimica Meyer, cat#6710-1000, Tapachula,
Mexico). Beginning at 09:00 h on each experimental day, we presented the
colony with a single sucrose concentration for 30 min, followed by a 5 min
pause (when no sucrose was available) before providing the next sucrose
concentration. We presented all five concentrations on each day, alternating
between ascending and descending concentration series on subsequent
experimental days. We thoroughly cleaned the feeder between concentration
changes. Each colony was used for two complete concentration series and thus
experienced both diminishing and increasing sucrose concentrations.
Foragers were individually marked either with Opalithplättchen honey
bee tags (colony BW5) or with small acrylic paint marks on their abdomens (all
other colonies). Every 5 min, we made an instantaneous count of the number of
foragers collecting sucrose solution at the feeder. Thus we made six counts
during each 30 min presentation of a particular sucrose concentration. To
examine the proportion of colony foraging elicited by different sucrose
concentration, we calculated the normalized forager census count
(FN) by dividing the census count by the largest census
count obtained for that colony at any sucrose concentration. We used a
circular grooved plate feeder [40 ml capacity, 10 cm diameter, 60 grooves,
design after description by von Frisch
(von Frisch, 1967)]. Foragers
fed ad libitum (feeder was never exhausted during the 30 min feeding
trial), and the feeder did not limit forager numbers because each feeder could
accommodate over 35 individuals; we observed a maximum of 25 foragers feeding
simultaneously. To determine forager size, we randomly selected 15 live
foragers from each colony, weighed them in plastic vials and measured their
length (from abdominal tip to anterior head) with calipers. Colonies were not
fed outside of the experimental period, but were not food deprived because
daily visual inspections revealed largely full honeypots in exposed areas of
each colony.
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). We recorded bee temperatures 5 s after they
had begun feeding on the feeder using a photographic infrared thermometer
(Raytek PhotoTemp MX6, San Diego, CA, USA; close-focus model) equipped with
True Spot laser sighting to precisely delineate the measured area (spot
measurement size adjustable to the diameter of a bumble bee thorax). Each time
we made a thermographic measurement, we measured air temperature 5 cm from the
feeder (Ta) using a weather meter (Kestrel 3000, Chester,
PA, USA). To calibrate the MX6 infrared thermometer, we inserted a type K
thermocouple into a dead bee whose internal and external temperature had
equilibrated to ambient, and then recorded its dorsal thoracic surface
temperature through the IR transparent plastic film. Equipment emissivity
values were then adjusted until both thermocouple and infrared temperature
readings matched. We measured Tth and
Ta, and calculated the difference between the thorax
temperature and the ambient air temperature at the feeder
[Tth (Stone,
1993)].
Statistical analyses
We used JMP IN v4.0.4 software to run ANOVA (standard least-squares model)
after checking for data normality through residual analysis
(Zar, 1984). Models with
multiple effects were run first with all interaction terms and then run as
simplified models without interactions if interactions were nonsignificant
(Zar, 1984). Values are
presented as means ± s.d. We considered results non-significant (NS) at
the critical value P 
0.05.
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Effect of ambient air temperature
We first examined the effect of Ta on
Tth at each sucrose concentration. In the overall model,
both Ta and sucrose concentration are significant effects,
but colony identity is not (two-factor ANOVA,
F2,1620=243.0, P<0.0001; individual effects:
Ta, F1,1620=1484.4,
P<0.0001; sucrose concentration;
F1,1620=1491.2, P<0.0001; colony identity NS;
interactions NS). We therefore pooled the data from all colonies and examined
the relationship between Tth and Ta at
each sucrose concentration. Foragers generally increased their thoracic
temperature above ambient at all sucrose concentrations, and the slope of
Tth on Ta is significantly less than
one for all concentrations (slope confidence intervals: P<0.001).
For clarity, Fig. 1 shows only
the highest and lowest concentrations. Note that with only the exception of
seven evidently ectothermic foragers (all at 0.5 mol l-1), all
other Tth values are higher than ambient air temperature
(Fig. 1). These seven different
bees (from colonies BW5, BW8 BW10, BW13 and BW14) also did not show any
noticeable abdominal respiratory movements. On average, forager
Tth increased by 0.53 to 0.66°C for each 1°C
increase in ambient air temperature over the range of sucrose concentrations
used.
Effect of sucrose concentration on thorax temperatures
We next examined the effect of sucrose concentration on
Tth (Table
1). The overall model for Tth with
sucrose concentration and colony identity is significant (two-factor ANOVA,
F6,1616=152.2, P<0.0001,
R2=0.36, interaction NS). Sucrose concentration is a
significant effect (F1,1616=475.4, P<0.0001,
SSsucrose=2292.6). Colony identity is also a significant
effect (F5,1616=106.6, P<0.0001,
SScolony=2569.4). A detailed analysis by colony reveals
that Tth significantly increases with sucrose
concentration with all colonies, with linear regression slope estimates
ranging from 1.2 to 2.4 (Table
2). Thus foragers increased their thoracic temperature excess, on
average, by 1.2 to 2.4°C for each 1 mol l-1 increase in sucrose
concentration.
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Effect of sucrose concentration on colony foraging
There is a significant effect of colony identity and sucrose concentration
on FN (the normalized forager census count, two-factor
model ANOVA, F6,1615=241.4, P<0.0001,
R2=0.47, interaction NS). Colony identity is a significant
effect (F5,1615=35.5, P<0.0001,
SScolony=4.5). Sucrose concentration is also a significant
effect (F1,1615=1082.2, P<0.0001,
SSsucrose=27.6), and accounts for approximately six times
more of the variance in FN than colony identity. A
detailed analysis by colony reveals that FN significantly
increased (P<0.0001) with sucrose concentration in each colony.
Linear regression slope estimates for the colonies fell into two groups: those
with slopes of 0.16-0.18 (colonies BW5, BW8, BW10 and BW14: group 1) and those
with slopes of 0.21 and 0.23 (colonies BW12 and BW13: group 2). We therefore
present these data pooled into two groups
(Fig. 2C), with sucrose
concentration accounting for 40% of the variance in FN of
group 1 (ANOVA F1,1120=739.1, P<0.0001) and
46% of the variance in FN of group 2 (ANOVA:
F1,498=424.5, P<0.0001). On average, the
proportion of feeding foragers increased by 18% with each 1 mol l-1
increase in sucrose concentration in group 1 and by 22% with each 1 mol
l-1 increase in group 2.
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Tth, each colony exhibited
the same trends of increasing Tth and increasing
FN with increasing sucrose concentration
(Table 2). Thus the phenomenon
of increasing thoracic temperature of foragers feeding while stationary upon
food with increasing caloric value has now been shown to occur in the Bombini
and may be homologous in all social bees in the Apidae.
A low Tth may be costly because it increases the time
between exploiting different inflorescences by prolonging pre-flight warm-up
or increasing escape times when avoiding predators. With a variety of bumble
bee species and worker sizes, a Tth of approximately
29-30°C is required for flight
(Heinrich, 1974). So
maintaining a high Tth, and thus flight readiness, may
allow workers to gamble on the chance of finding a new food source
(Heinrich and Heinrich,
1983a). For food of lower quality, less energy could be spent on
maintaining higher thoracic temperature to optimize net caloric returns to the
colony (Stabentheiner et al.,
1995). Body temperature decreases when foraging on relatively poor
quality food could have evolved in bumble bees as an energyconserving strategy
under active physiological control or perhaps to a lack of direct energy
supplies (Heinrich and Heinrich,
1983a), although in honeybees there is no correlation between
haemolymph sugar levels and body temperatures, except for a slight effect with
highly dilute sucrose solution (Blatt and
Roces, 2001; Blatt and Roces,
2002). High Tth may also be adaptive on
natural food sources to properly harvest the food, particularly pollen
(Feuerbacher et al., 2003).
For example, B. terricola workers may have maintained a high
Tth to collect pollen by twirling around Spiraea
latifolia inflorescences (Heinrich
and Heinrich, 1983a).
Colonies were of different sizes and were collected at different times of
year and thus potentially at different life stages (S.C., unpublished
observations). Both of these effects may account for differences in the
proportion of workers activated to forage at given sucrose concentrations, in
addition to differences in colony food stores. We found colony differences in
slope and y-intercept for the effect of sucrose concentration on
Tth and FN, although in all cases, there
was a significant positive effect of sucrose concentration on
Tth and FN
(Table 2). In particular, our
largest colony, BW5, exhibited the strongest correlations between sucrose
concentrations and Tth
(R2=0.43). We speculate that worker thresholds for sucrose
collection and thus the perceived quality of different sucrose concentrations
may also have varied with either colony stage (whether the colony was at the
beginning of its life cycle and growing or near the end of its life cycle and
collecting relatively little food) or food stores. With our current data, we
are unable to determine whether seasonality and colony life stage play a role
in finely modulating the effects of sucrose concentration on
Tth and FN, although this would
be important to test in future studies.
It is relevant to consider how our experimental design may have affected
our measurements. Floral nectars occur at a variety of sugar concentrations
(Baker and Baker, 1982) and
generalist neotropical bee foragers collect nectars ranging from 10%-70% sugar
by mass [with means of 38%, 44% and 48% for Euglossini, Meliponini and
Centridini, respectively (Roubik et al.,
1995)]. We therefore used sucrose concentrations ranging from
0.5-2.5 mol l-1 (16% to 65% by mass), with the highest sucrose
concentration (2.5 mol l-1) used to provide comparative data with
foraging studies on other social bees.
We conducted our experiments with colonies foraging in foraging arenas, a
standard experimental design for investigations of bumble bee foraging
(Chittka et al., 2003;
Dornhaus and Cameron, 2003;
Dornhaus and Chittka, 1999;
Dornhaus and Chittka, 2004;
Dyer et al., 2006;
Spaethe et al., 2001). In most
cases, bumble bees walked to the food source, but some flew and we did not
detect any differences between the Tth effect of sucrose
concentration on bees that had walked or flown to the food source.
Nonetheless, it would be desirable to verify the effect of sucrose
concentration on Tth with flying bees using a large flight
arena.
In B. wilmattae the average Tth
increased by 4.2°C with each 1 mol l-1 increase in sucrose
concentration. This is a greater increase than is found in honey bees
[1.5°C increase in thoracic temperature per doubling of the sucrose
concentration (Schmaranzer and
Stabentheiner, 1988)]. Foragers of the stingless bee M.
panamica increased Tth by 0.9°C per 1 mol
l-1 increase in sucrose concentration
(Nieh and Sánchez,
2005). Body size may play a role in the effect of sucrose
concentration on Tth excess, because the bumble bee
foragers that we studied are larger than honey bees, which are in turn larger
than M. panamica. This may be an interesting question to pursue in
future comparative studies within and between bee groups.
In our study, the tropical species, B. wilmattae, maintained
thoracic temperatures on average between 29°C and 32°C while foraging,
similar to the range reported by Heinrich and Heinrich in a study of temperate
Bombus terricola foraging on field spiraea (Spiraea
latifolia) and goldenrods (Solidago sp.)
(Heinrich and Heinrich,
1983a). Because there have been no similar studies on the effect
of sucrose concentration on temperate bumble bees foraging while perched,
future investigations may look for differences between the
Tth and Tth of tropical and
temperature bumble bees flying to food sources. For example, at 2.5 mol
l-1, we found an average Tth of 31.6°C at
an average Ta of 24.7°C. Studies conducted under
similar ambient temperatures and sucrose concentrations will be necessary to
draw conclusions on potential differences or similarities between tropical and
temperate bumble bees.
The forager abdominal pumping movements that we observed during our
experiments are common in a variety of insects, and are generally accompanied
by a rapid rise in thoracic temperature
(May, 1979). In particular,
such movements are associated with thoracic heat generation in a wide variety
of bumble bee species (Heinrich,
1993). Fibrillar muscles are responsible for the generation of
bumble bee thoracic heat (Heinrich and
Kammer, 1973), and contractions of B. impatiens thoracic
flight muscles, particularly the dorsoventral muscle fibers, were associated
with flight warmup (Esch and Goller,
1991). In the shade (as in our experiments), the difference
between ambient and thoracic temperatures is primarily a result of flight
metabolism or thermoregulation through muscular activity during the times when
they are perched on flowers (Heinrich,
1972a).
Previous studies hint at a similar effect of food quality on
Tth. When Heinrich added concentrated, viscous sugar syrup
to fireweed flowers, he reported that feeding B. vagans foragers held
their wings folded dorsally with rapid abdominal respiratory movements (as we
observed in our study) (Heinrich,
1972b). After 2 min of feeding, bees had an average
Tth of 34.8°C, significantly higher
(P<0.05) than those foraging on fireweed with normal,
un-supplemented nectar at the same range of ambient air temperatures. There
were significant differences in Tth based upon flower
type: higher Tth in bumble bees foraging on raspberry
flowers than on fireweed or spiraea
(Heinrich and Heinrich,
1983b). Based upon our results, we suggest that the quality of
nectar reward may have contributed to some of these Tth
differences in B. terricola. For B. terricola foraging in
the field on Asclepias syriaca nectar, mean Tth
was relatively independent from Ta (regulated
approximately near 36°C, depending upon exposure to shade or sun), unlike
mean Tth of bees foraging from Spiraea latifolia
or Solidago canadensis, which were more strongly influenced by
ambient air temperatures. Interestingly, individual A. syriaca
flowers contained larger volumes of nectar than S. latifolia or
S. canadensis flowers (Heinrich,
1972a). These results suggest that volume of a reward may also
have an influence on Tth, as is found in honey bees, where
higher nectar flow rates resulted in higher Tth
(Waddington, 1990). We
hypothesize that bumble bee forager Tth will be correlated
generally and positively with nectar sugar content and flow rate.
Nieh and Sánchez hypothesized that all corbiculate bees possess the
ability to adjust body temperature based upon food rewards
(Nieh and Sánchez,
2005), and supporting data had been found in the honey bees and
stingless bees (Nieh and Sánchez,
2005; Stabentheiner,
2001). The present results demonstrate that at least one species
within the bumble bees increases its thoracic temperature with increased
carbohydrate reward. Whether this effect can be observed in other groups of
bees, such as some of the Halictidae, remains to be demonstrated, but we
suggest that this is quite likely. The modulation of thoracic temperature in
accordance with food value may be a widespread adaptation facilitating the
rapid collection of good food in flying Hymenoptera.
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