Summary
The temperature at the centre, the periphery and the entrance of a honey bee colony (Apis mellifera carnica) was continuously determined during the summer season and the broodless time in winter. During the summer season the temperature in the brood nest averages 35.5°C with brief excursions up to 37.0°C and down to 33.8°C. Increasing environmental temperatures resulted in linear increases in the temperature of the hive entrance, its periphery and its centre. The temperature in the centre of an overwintering cluster is maintained at an average value of 21.3°C (min 12.0°C, max 33.5°C). With rising ambient temperatures the central temperature of a winter cluster drops whereas the peripheral temperature increases slightly. With decreasing external temperatures the peripheral temperature is lowered by a small amount while the cluster's centre temperature is raised. Linear relationships are observed between the central and the ambient temperature and between the central temperature and the temperature difference of the peripheral and the ambient temperatures. The slopes point to two minimum threshold values for the central (15°C) and the peripheral temperature (5°C) which should not be transgressed in an overwintering cluster. Microcalorimetric determinations of the heat production were performed on the three castes of the honey bee: workers, drones and queens of different ages. Among these groups single adult workers showed the highest heat production rates (209 mW·g−1) with only neglectible fluctuations in the heat production rate. Juvenile workers exhibited a mean heat production rate of 142 mW·g−1. The rate of heat production of adult workers is strongly dependent upon the number of bees together in a group. With more than 10 individuals weight-specific heat dissipation remains constant with increasing group sizes at a level approximately 1/17 that of an isolated bee. Differences are seen between the rates of virgin (117 mW·g−1) and laying (102 mW·g−1) queens. Laying queens showed less thermal fluctuations than virgin queens. High fluctuations in heat production rates are observed for drones. In both groups (fertile, juvenile) phases of high and extremely low activity succeed one another. The heat production of juvenile drones was 68 mW·g−1, that of fertile drones 184 mW·g−1 due to stronger locomotory activities.
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References
Allen MD (1959) Respiration rates of worker honeybees of different ages and at different temperatures. J Exp Biol 36:92–101
Bachem I, Lamprecht I, Shaarschmidt B (1980) Energetical investigations on the ecologic system: Ant hill. In: Hemminger W, Wiedemann HG (eds) Thermal analysis. Birkhäuser Basel: 571–575
Bachem I, Lamprecht I (1983) The hill of the red wood antsFormica polyctena as a model of an ecological system. Zurnal Obscej Biologii 44:114–123
Cahill K, Lustick S (1976) Oxygen consumption and thermoregulation inApis mellifera. Comp Biochem Physiol 55A:355
Calvet E, Prat H (1956) Microcalorimetrie—applications physico-chimiques et biologiques. Masson, Paris
Dontsova GV, Zotin AI (1982) Relationship between maximal metabolism, body weight and standard metabolism of animals. In: Lamprecht I, Zotin AI (eds) Thermodynamics and kinetics of biological processes. De Gruyter, Berlin, pp 369–385
Free JB, Simpson J (1963) The respiratory metabolism of honey-bee colonies at low temperatures. Ent Exp Appl 6:234–238
Free JB, Spencer-Booth Y (1958) Observations on the temperature regulation and food consumption of honeybees (Apis mellifera). J Exp Biol 35:930–937
Free JB, Spencer-Booth Y (1959) Temperature regulation of honeybees. Bee World 40:173–177
Free JB, Spencer-Booth Y (1960) Chill-coma and cold death temperatures ofApis mellifera. Ent Exp Appl 3:222–230
Harrison JM (1987) Roles of individual honeybee workers and drones in colonial thermogenesis. J Exp Biol 129:53–61
Heinrich B (1980) Mechanism of body-temperature regulation in honeybees,Apis mellifera. II. Regulation of thoraric temperature at high air temperatures. J Exp Biol 85:73–87
Heinrich B (1981) Energetics of honeybee swarm thermoregulation. Science 212:565–566
Hemminger W, Höhne G (1984) Calorimetry—fundamentals and practice. Verlag Chemie, Weinheim
Heran H, Crailsheim K (1988) Energy requirements of bees (Apis mellifera carnica Pollm.) in free flight, with and without additional load. In: Energy transformations in cells and animals, 10th Conf Europ Comp Physiol and Biochem Innsbruck: 77
Herman D, Lemasson M, Semaille R, Van Impe G (1982) Mesure de la consommation d'oxygene de l'abeille mellifere (Apis mellifica L.) par polarographie. Z Ang Ent 93:284–291
Hocking B (1953) The intrinsic range and speed of flight of insects. Trans Roy Ent Soc Lond 104:218–234
Kleiber M (1961) The fire of life. An introduction to animal energetics. Wiley, New York
Kronenberg F (1979) Colonial thermoregulation in honey bees. Doctoral thesis, Stanford University, Stanford CA
Kronenberg F, Heller HC (1982) Colonial thermoregulation in honey bees (Apis mellifera). J Comp Physiol 148: 65–76
Lamprecht I (1983) Application of calorimetry to different biological fields and comparison with other methods. Boll Soc Natur Napoli 92:515–542
Lindauer M (1951) Die Temperaturregulierung der Bienen bei Stocküberhitzung. Naturwissenschaften 38:308–309
Lindauer M (1954) Temperaturregulierung und Wasserhaushalt im Bienenstaat. Z Vergl Physiol 36:391–432
Lorenz RJ (1984) Grundbegriffe der Biometrie. Fischer, Stuttgart New York
McNeil DR (1977) Interactive data analysis. A practical primer. Wiley, New York, p 186
Moffett JO, Lawson FA (1975) Effect ofNosema-infection on O2 consumption by honey bees. J Econ Entom 68:627–629
Nagy KA, Stallone JN (1976) Temperature maintenance and CO2 concentration in a swarm cluster of honey bees,Apis mellifera. Comp Biochem Physiol 55A:169–171
Ritter W (1982) Experimenteller Beitrag zur Thermoregulation des Bienenvolkes (Apis mellifera L.). Apidologie 13:169–195
Roth M (1964) Adaptation de la thermogenese a la temperature ambiante et effet d'economie thermique du groupe chez l'Abeille (Apis mellifica L.). CR Acad Sci Paris 258:5534–5537
Roth M (1965) La production de chaleur chezApis mellifera L. Ann Abeille 8(1):5–77
Scholze E, Pichler H, Heran H (1964) Zur Entfernungsschätzung der Bienen nach dem Kraftaufwand. Naturwissenschaften 51:69–70
Simpson J (1961) Nest climate regulation in honey bee colonies. Science 133:1327–1333
Southwick EE (1982) Metabolic energy of intact honey bee colonies. Comp Biochem Physiol 71A:277–281
Southwick EE, Mugaas J (1971) A hypothetical homeotherm: The honeybee hive. Comp Biochem Physiol 40A:935–944
Stussi TH (1972) L'heterothermie de l'abeille. Arch Sci Physiol 26:131–159
Wohlgemuth R (1957) Die Temperaturregulation des Bienenvolkes unter regeltheoretischen Gesichtspunkten. Z Vergl Physiol 40:119–161
Worswick PVW (1987) Comparative study of colony thermoregulation in the African honeybee,Apis mellifera adansonii Latreille and the Cape honeybee,Apis mellifera capensis Escholtz. Comp Biochem Physiol 86A:95–102
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Fahrenholz, L., Lamprecht, I. & Schricker, B. Thermal investigations of a honey bee colony: thermoregulation of the hive during summer and winter and heat production of members of different bee castes. J Comp Physiol B 159, 551–560 (1989). https://doi.org/10.1007/BF00694379
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DOI: https://doi.org/10.1007/BF00694379