Summary
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1.
The tiger beetle Cicindela hybrida is a diurnal predator inhabiting open sandy areas. The activity pattern on a sunny day in May with a mean maximum surface temperature of 40°C is described (Fig. 2). The inactive period is spent in burrows in the sand and it is suggested that a threshold of 19°C releases the daily round of activity (Fig. 5). The animals appear on the sand between 7.00 and 10.00 and the number reaches a maximum at 34–42°C (surface temp.). The duration of the activity period is indirectly determined by the number of available prey which is maximal at 36°C and decreases both at higher and lower temperatures. Mean onset and termination of activity occur at about 28°C (surface temp.) when the expected capture rate is 3 per hour. In actograph experiments, onset was controlled by the illumination and occurred several hours before “dawn” (Fig. 9).
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2.
The preferred body temperature is at about 35°C and thermoregulatory behaviour patterns are used in order to approach this. At low ambient temperatures, body temperature is increased by sun-basking, while at high temperatures stilting is used to prevent it from increasing above 35°C. If the temperature becomes intolerably high, the animals dig into the sand (Figs. 8, 16). Measurements of body temperatures in the field show that tiger beetles have partial regulation (Fig. 10) and it is suggested that this is because the cost of thermoregulation is low, but prey is not abundant enough to allow a full exploitation of this, and predation (hunger) interferes with the thermoregulation.
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3.
An estimation of the daily water loss under field conditions is presented based on measurements of the water loss in the laboratory at different temperatures and relative humidities. These values are weighted by the times actually spent at different combinations in the field (Figs. 17, 19). The loss amounts to about 10% per day of initial body weight, and it is concluded that tiger beetles have not evolved any special adaptations with respect to this factor.
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References
Ahearn, G.A., Hadley, N.F.: The effects of temperature and humidity on water loss in two desert tenebrionid beetles, Eleodes armata and Cryptoglossa verrucosa. Comp. Biochem. Physiol. 30, 739–749 (1969)
Alexander, A.J., Ewer, D.W.: Temperature adaptive behaviour in the scorpion Opisthophthalmus latimanus. J. Exp. Biol. 35, 349–359 (1958)
Bolwig, N.: Experiments on the regulation of body temperature of certain tenebrionid beetles. J. Ent. Soc. S. Afr. 20, 454–458 (1957)
Chapman, R.N., Michel, C.E., Parker, J.R., Miller, G.E., Kelly, E.G.: Studies in the ecology of sand dune insects. Ecology 7, 416–426 (1926)
Clench, H.K.: Behavioral thermoregulation in butterflies. Ecology 47, 1021–1034 (1966)
Cloudsley-Thompson, J.L.: Studies in diurnal rhythms-VI. Bioclimatic observations in Tunisia and their significance in relation to the physiology of the fauna, especially woodlice, centipedes, scorpions and beetles. Ann. Mag. Nat. Hist. 9, 305–329 (1956)
Dawson, W.R.: On the physiological significance of the preferred body temperature of reptiles. In: Perspectives of Biophysical Ecology, Ecological Studies Vol. 12, (eds. D.M. Gates and R.B. Schmerl), pp. 443–473 (1975)
Douwes, P.: Activity in Heodes virgaureae in relation to air temperature, solar radiation and time of day. Oecologia (Berl.) 22, 287–298 (1976)
Edney, E.B.: Water balance in desert arthropods. Science 156, 1059–1066 (1967)
Edney, E.B.: Water balance in Land Arthropods. Zoophysiology and Ecology Vol. 9. Berlin Heidelberg New York: Springer Verlag 1977
Edney, E.B., Haynes, S., Gibo, D.: Distribution and activity of the desert cockroach Arenivaga investigata in relation to microclimate. Ecology 55, 420–427 (1974)
Faasch, H.: Beobachtungen zur Biologie und zum Verhalten von Cicindela hybrida und Cicindela campestris und experimentelle Analyse ihres Beutefangsverhaltens. Zool. Jb. Syst. 95, 477–522 (1968)
Fraenkel, G.: Die Orientierung von Schistocerca gregaria zu strahlender Wärme. Z. vergl. Physiol. 13, 300–313 (1930)
Gärdefors, D.: Temperature-humidity “organ” experiments with three species of grasshoppers belonging to the family of Acrididae. Ent. exp. appl. 9, 395–401 (1966)
Hadley, N.F.: Micrometeorology and energy exchanges in two desert arthropods. Ecology 51, 547–558 (1970)
Hamilton, W.J.: Competition and thermoregulatory behavior of the Namib Desert tenebrionid beetle genus Cardiosis. Ecology 52, 810–822 (1971)
Hamilton, W.J.: Coloration and its thermal consequences for diurnal desert insects. In: Environmental Physiology of Desert Organisms (ed. N.T. Hadley), pp. 67–85 1975
Heath, J.E.: Temperature regulation and diurnal activity in horned lizards. Univ. Calif. Publ. Zool. 64, 97–130 (1965)
Heath, J.E., Wilkin, P.J.: Temperature responses of the desert cicada, Diceroprocta apache. Physiol. Zool. 43, 145–154 (1970)
Henwood, K.: A field-tested thermoregulation model for two diurnal Namib Desert tenebrionid beetles. Ecology 56, 1329–1342 (1975)
Hoffmann, K.: Synchronisation der circadianen Aktivitätsperiodik von Eidenchsen durch Temperaturcyclen verschiedener Amplitude. Z. vergl. Physiol. 58, 225–228 (1968)
Holm, E., Edney, E.B.: Daily activity of Namib Desert arthropods in relation to climate. Ecology 54, 45–57 (1973)
Huey, R.B.: Behavioral thermoregulation in lizards; importance of associated costs. Science 184, 1001–1003 (1974)
Huey, R.B., Slatkin, M.: Cost and benefits of lizard thermoregulation. Quart. Rey. Biol. 51, 363–384 (1976)
Humpreys, W.F.: Behavioral thermoregulation in a wolf spider. Nature 251, 502–503 (1974)
Kevan, P.G., Shorthouse, J.D.: Behavioural thermoregulation by high arctic butterflies. Arctic 23, 268–279 (1970)
Larochelle, A.: North American amphibians and reptiles as predators of tiger beetles. Cicindela 6, 83–86 (1974)
Larochelle, A.: Birds as predators of tiger beetles. Cicindela 7, 1–7 (1975a)
Larochelle, A.: North American mammals as predators of tiger beetles. Cicindela 7, 9–11 (1975b)
Templeton, J.R.: Reptiles. In: Comparative Physiology of Thermoregulation, Vol. 1 (ed. G.C. Whittow), pp. 167–221, Academic Press 1970
Vielmetter, W.: Physiologie des Verhaltens zur Sonnenstrahlung bei dem Tagfalter Argynnis paphia — I. Untersuchungen in Freiland. J. Insect Physiol. 2, 13–37 (1958)
Watt, W.B.: Adaptive significance of pigment polymorphisms in Colias butterflies. — I. Variation of melanin pigment in relation to thermoregulation. Evolution 22, 437–458 (1968)
Willis, H.C.: Bionomics and zoogeography of tiger beetles of saline habitats in central United States. Univ. Kans. Sci. Bull. 47, 145–313 (1967)
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Dreisig, H. Daily activity, thermoregulation and water loss in the tiger beetle Cicindela hybrida . Oecologia 44, 376–389 (1979). https://doi.org/10.1007/BF00545242
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DOI: https://doi.org/10.1007/BF00545242