Abstract
Embryonal development of the five congeners Protonemura auberti Illies, 1954, P. hrabei Rauser, 1956, P. meyeri (Pictet, 1841), P. nitida (Stephens, 1835), and P. praecox (Morton, 1894) was studied under various laboratory temperatures and different photoperiods.
Mean number of eggs in field collected batches was between 470 (P. praecox) and 1211 (P. auberti). Spring species had smaller egg batches than autumn species (Table 1). Mean hatching success in the laboratory was 50–100% at 2–18 °C. In most species hatching success decreased slightly with increasing temperature (Figs. 1a-e). None of the eggs incubated at 24 °C developed. Hatching pattern followed an asymmetric frequency distribution. In general, the hatching periods were the shorter the higher the incubation temperature.
Embryonic development of all five species was inversely temperature dependent (Figs. 2a-e), and well described by a power law relationship (Figs. 3a-e). Interspecific differences in incubation periods were notable at nearly all temperatures (Fig. 4). There was a distinct interspecific sequence in length of incubation period (with steps of about 4 days), which was the same as can be seen in the flight periods: The later the species flies the longer the incubation period. Temperature fluctuations and variations in photoperiod had no influence on incubation and hatching periods or hatching success.
The thermal demand of the egg stage neither explains the recent geographical distribution of the Protonemura species, nor does it directly correspond to the field temperatures common during their egg development. However, it is optimal in respect to resource partitioning between the five species, with the consequence of temporal displacement of life cycles.
Derived from Brittain's (in press) proposal to compare the two constants ‘a’ and ‘b’ of the regressions describing the temperature dependence of embryonal development, a new index (Integral Development Time, IDT) indicating the thermal demand was created for easier comparison of numerous species (Table 2). Evaluation of the IDT for various species of Plecoptera (Fig. 5) suggests that species belonging to the family group Systellognatha generally have higher thermal requirements in the egg stage than species belonging to the Euholognatha.
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References
Bengtson, J., 1984. Autecological studies of Nemoura cinerea (Retz.). Arch. Hydrobiol. 100: 299–309.
Brittain, J. E., 1977. The effect of temperature on the egg incubation period of Taeniopteryx nebulosa (Plecoptera). Oikos 29: 302–305.
Brittain, J. E., 1978. Semivoltinism in mountain populations of Nemuralla pictetii (Plecoptera). Oikos 30: 1–6.
Brittain, J. E., 1987. Life history strategies in Ephemeroptera and Plecoptera. In Campbell, I. (ed.) Symposium on Life History Strategies in Ephemeroptera and Plecoptera, Marysville, Australia, Feb. in press.
Brittain, J. E. & A. Lillehammer, 1987. Variability in the rate of egg development of the stonefly Nemoura cinerea (Plecoptera). Freshw. Biol. 17: 565–569.
Brittain, J. E., A. Lillehammer & S. J. Saltveit, 1984. The effect of temperature on intraspecific variation in egg biology and nymphal size in the stonefly Capnia atra (Plecoptera). J. Anim. Ecol. 53: 161–169.
Brittain, J. E. & R. A. Mutch, 1984. The effect of water temperature on the egg incubation period of Mesocapnia oenone (Plecoptera) from the Canadian Rocky Mountains. Can. Ent. 116: 549–554.
Brock, V., 1986. Vergleichende Untersuchungen zur Entwicklung der Steinfliegen. Diss. Univ. Hamburg.
Dittmar, H., 1955. Ein Sauerlandbach — Untersuchungen an einem Wiesen-Mittelgebirgsbach. Arch. Hydrobiol. 50: 307–552.
Elliott, J. M., 1984. Hatching time and growth of Nemurella pictetii (Plecoptera - Nemouridae) in the laboratory and a Lake District stream. Freshwat. Biol. 14: 491–499.
Elliott, J. M., 1986. The effect of temperature on the egg incubation period of Capnia bifrons (Plecoptera: Capniidae) from Windermere (English Lake District). Holarct. Ecol. 9: 113–116.
Elliott, J. M., 1987. Egg hatching and resource partitioning in stoneflies: The six British Leuctra spp. (Plecoptera: Leuctridae). J. Amin. Ecol. 56: 415–426.
Elliott, J. M., 1988. Egg hatching and resource partitioning in stoneflies (Plecoptera): ten British species in the family Nemouridae. J. Anim. Ecol. 57: 201–215.
Ernst, M. R., T. L. Beitinger & K. W. Stewart, 1984. Critical thermal maxima of nymphs of three Plecoptera species from an Ozark Foothill stream. Freshwat. Invertebr. Biol. 80, 3: 80–85.
Harper, P. P., 1973a. Emergence, reproduction and growth of setipalpian Plecoptera in Southern Ontario. - Oikos 24: 94–107.
Harper, P. P., 1973b. Life histories of Nemouridae and Leuctridae in Southern Ontario (Plecoptera). Hydrobiologia 41: 309–356.
Harper, P. P. & H. B. N. Hynes, 1972. Life histories of Capniidae and Taeniopterygidae (Plecoptera) in Southern Ontario. Arch. Hydrobiol. Suppl. 40: 274–314.
Humpesch, U. H., 1982. Effect of fluctuating temperature in the duration of embryonic development in two Ecdyonurus spp. and Rhithrogena cf hybrida (Ephemeroptera) from Austrian streams. Oecologia (Berl.) 55: 285–288.
Humpesch, U. H., 1984. Egg development of non-diapausing exopterygote aquatic insects occuring in Europe. Sitzungsber. österr. Akad. Wiss. 193 (6–10): 329–341.
Illies, J., 1978. Limnofauna Europaea. Gustav Fischer, Stuttgart New York, 2. Auflage.
Jacob, U., 1986. Analyse der Ephemeroptera-Jahresemergenz des Breitenbaches bei Schlitz/Hessen (Bundesrepublik Deutschland). Arch. Hydrobiol. 107: 215–248.
Khoo, S. G., 1964. Studies on the biology of stoneflies. Ph. D. thesis, Univ. Liverpool.
Knauf, W., 1969. Faunistisch ökologische Untersuchungen an der Wiesent, einem Karstfluß der nördlichen Fränkischen Alp, mit besonderer Berücksichtigung der Fließgewässerregionen. Diss. Univ. Erlangen.
Kracht, M., 1982. Zur Steinfliegen-Fauna des Vogelsberges, Hessen. Senckenbergiana biol. 62: 287–294.
Lamb, R. J., G. H. Gerber, 1985. Effects of temperature on the development, growth, and survival of larvae and pupae of a north-temperate chrysomelid beetle. Oecologia 67: 8–18.
Lillehammer, A., 1975. Norwegian stoneflies IV, Laboratory studies on ecological factors influencing distribution. Norw. J. Ent. 22: 99–108.
Lillehammer, A., 1985. Temperature influence on egg incubation period and nymphal growth on the stoneflies Leuctra digitata and Leuctra fusca (Plecoptera: Leuctridae). Ent. Gener. 11: 59–67.
Lillehammer, A., 1986. The effect of temperature on the egg incubation period and nymphal growth of two Nemoura species (Plecoptera) from subarctic Fennoscandia. Aquat. Insects 8: 223–237.
Lillehammer, A., 1987a. Intraspecific variation in the biology of eggs and nymphs of Norwegian populations of Leuctra hippopus (Plecoptera). J. Nat. Hist. 21: 29–41.
Lillehammer, A., 1987b. Egg development of the stoneflies Siphonoperla burmeisteri (Chloroperlidae) and Dinocras cephalotes (Perlidae). Freshwat. Biol. 17: 35–39.
Marten, M., 1983. Die Ephemeropteren, Plecopteren, Heteropteren und Coleopteren der Fulda. - Diplomarbeit FU Berlin.
Marten, M., 1987. Labor- und Freilanduntersuchungen zur Autökologie von Protonemura-Arten (Plecoptera: Insecta) unter besonderer Berücksichtigung des Einflusses der Temperatur auf die Embryonal- und Larvalentwicklung. Diss. Univ. Kassel.
Marten, M., Zwick, P., in press. The temperature dependence of embryonal and larval development of Protonemura intricata (Ris, 1902) (Insecta: Plecoptera: Nemouridae). Freshwat. Biol. 21.
Matthias, U., 1983. Der Einfluß der Versauerung auf die Zusammensetzung von Bergbachbiozönosen. Arch. Hydrobiol. Suppl. 65: 407–483.
Mellors, W. K. & A. Allegro, 1984. Comparison of constant and alternating temperatures for determining developmental rates of Mexican bean beetle eggs and pupae. Ann. Ent. Soc. Am. 77: 6–10.
Mutch, R. A. & G. Pritchard, 1986. Development rates of eggs of some Canadian stoneflies (Plecoptera) in relation to temperature. J. N. Am. Benthol. Soc. 5: 272–277.
Remmert, H. & K. Wünderling, 1970. Temperature differences between Arctic and Alpine meadows and their ecological significance. Oecologia 4: 208–210.
Saltveit, S. J., 1979. Field and laboratory studies on the life history of three species of Amphinemura. Gewässer und Abwässer 64: 30–31.
Saltveit, S. J. & A. Lillehammer, 1984. Studies on egg development in the Fennoscandian Isoperla species (Plecoptera). Annls. Limnol. 20: 91–94.
Strange, C. D., 1985. The effect of temperature on the egg development of Protonemura meyeri Pictet (Plecoptera, Nemouridae). Proc. R. Ir. Acad. 85 B 8: 101–106.
Sweeney, B. W., 1978. Bioenergetic and developmental response of a mayfly to thermal variation. Limnol. Oceanogr. 23: 461–477.
Sweeney, R. K. & J. Schnack, 1977. Egg development, growth and metabolism of Sigara alternata (Say) (Hemiptera: Corixidae) in fluctuating thermal environments. Ecology 58: 265–277.
Vaught, G. L. & K. W. Stewart, 1974. The life history and ecology of the stonefly Neoperla clymene (Newmann) (Plecoptera: Perlodidae). Ann. Ent. Soc. Am. Columbus 67: 167–178.
Ward, J. V. & A. J. Stanford, 1982. Thermal response in the evolutionary ecology of aquatic insects. Ann. Rev. Ent. 27: 97–117.
Wolf, B., 1986. Der Lebenszyklus von Nemurella pictetii unter besonderer Berücksichtigung ihres Polyvoltinismus. Diplomarbeit Univ. Giessen.
Zwick, P., 1969. Beitrag zur Kenntnis der Plecopterenfauna der Fulda und ihres Einzuggebietes in der Rhön und dem Vogelsberg. Beitr. Naturk. Osthessen 1: 65–76.
Zwick, P., 1973. Insecta: Plecoptera, Phylogenetisches System und Katalog. in: Das Tierreich, Lfg. 94, Walter de Gruyter, Berlin, New York: 1–465.
Zwick, P., 1980. Plecoptera/Steinfliegen. Handb. Zool. 4, 2/7: 1–115.
Zwick, P., 1981. Diapause development of Protonemura intricata (Plecoptera: Nemouridae). Verh. int. Ver. Limnol. 21: 1607–1611.
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Marten, M. Interspecific variation in temperature dependence of egg development of five congeneric stonefly species (Protonemura Kempny, 1898, Nemouridae, Plecoptera). Hydrobiologia 199, 157–172 (1990). https://doi.org/10.1007/BF00005607
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DOI: https://doi.org/10.1007/BF00005607