Abstract
Relationships between changes of two species of terrestrial chironomids(Smittia cf. aterrima andBryophaenocladius cf. virgo) and changes of vegetation cover during succession were studied with respect to plant — chironomid interaction in particular stages of chironomid life cycle. Several vegetation types forming vegetation mosaics in suburban fallow were distinguished according to their spatial architecture (height; density etc.). Abundance of chironomid larvae in particular type of vegetation and an area covered by these vegetation types were studied for three years. During one year the effect of vegetation types on density of aerial drift, oviposition habitat preference and adult emergence was studied in detail. Aerial drift was studied using pan traps, oviposition using soil sampling and adult emergence using emergence trap. Main results were similar for both species. Chironomid larvae were abundant in soil in initial years of succession. They were concentrated in patches with open and low height vegetation. Later their abundance decreased corresponding to a reduction of open and low vegetation areas. Greater density of aerial drift and oviposition preference was observed in areas of open and low vegetation. The success of larval development agreed with oviposition preference for winter larval generation only. The less preferred habitats seemed to be more suitable for summer generation. The results indicated that successional changes of terrestrial chironomids can be explained by the effect of vegetation cover on oviposition habitat preference.
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References
Bailliot, S. and P. Trehen (1974) Variations de 1’ attractivite des pieges colores de Moericke en fonction de la localisation spatio — temporelle de 1 emergence, des comportements sexuels et des phases de dispersion de quelques especes de Dipteres.Annales de’ Zoologie Ecologie Animale 6: 574–584.
Blaustein, L. and B. P. Kotier (1993) Oviposition habitat selection by the mosquitoCuliseta longiareolata: effect of conspeciflcs, food and green toad tadpoles.Ecological Entomology 18: 104–108.
Carter, A., J. Lagerlöf and E. Steen (1985) Effect of major disturbances in different agricultural cropping systems on soil macroarthropods.Acta Agriculturae Scandinavica 35: 67–77.
Caspary V. G. and A. E. R. Downe (1971) Swarming and mating ofChironomus riparius (Diptera: Chironomidae).Canadian Entomologist 103: 44–448.
Connel, J. H. and O. R. Stayer (1977) Mechanism of succession in natural communities and their role in community stability and organization.American Naturalist 111: 1110–1144.
Corbet, S. A. (1994) Insect, plants and succession: advantages of long-term set aside.Agriculture Ecosystems and Environment 53: 201–217.
Danielson, B. J. (1991) Communities in a landscape: the influence of habitat heterogenity on the interaction between species.American Naturalist 168: 1105–1120.
Delettre, Y. R. (1986) La colonisation de biotopes multiples: une alternative ŕ la résistance in situ aux conditions mésologiques défavorables. Cas deLimnophyes minimus (Mg.), Diptére Chironomidae ŕ larves édaphiques des landes armoricaines.Revue d’Ecologie et Biologie du Sol 23: 29–38.
Delettre, Y. R. (1988) Chironomid wing length, dispersal ability and habitat predictability.Holarctic Ecology 11: 166–170.
Delettre, Y. R. (1994) Fire disturbance of a chironomid (Diptera) community in heathlands.Journal of Applied Ecology 31: 560–570.
Delettre, Y. R. and J. Lagerlöf (1992) Abundance and life history of terrestrial Chironomidae (Diptera) in four Swedish agricultural cropping systems.Pedobiologia 36: 69–78.
Delettre, Y., P. Trehen and P. Grootaert (1992) Space heterogenity, space use and short range dispersal in Diptera: A case study.Landscape Ecology 6: 175–181.
Downie, I. S. (1995) Habitat preference of sub-montane spiders in northern England.Ecography 18: 51–61.
Ducrotoy, J. P. (1980) Adaptations spatio-temporelles de chironomides (Insectes: Dipteres) dans un habitat semi-permanent du massif de Paimpont.Bullten d’Ecologie 11: 633–645.
Fenny, P. (1975) Biochemical coevolution between plants and their insects herbivores, pp. 1–19. In L. E. Gilbert and P. H. Raven (eds.)Coevolution of animals and plants. Texas Univ. Press, Augustin.
Ferrington, L. C. Jr. (1987) Microhabitat preference of larvae of three Orthocladinae species (Diptera, Chironomidae) in Big Springs a sandbottom spring in the high plains of western Kansas.Entomologica Scandinavica, Supplement 29: 361–368.
Frouz, J. (1994) Changes in terrestrial chironomid community (Diptera: Chironomidae) during secondary succession in old fields.Pedobiologia 32: 334–343.
Frouz, J. and A. Lukešová (1995) Food preference of two species of terrestrial chironomids (Diptera: Chironomidae).Dipterologica Bohemoslovaca 7: 41–46.
Fry, G. L. A. and W. J. Robson (1994) The effects of field margins on butterfly movement, pp. 111–116.In N. Boatman (ed.)Field margins integrating agriculture and conservation. BCPC Monograph No. 58.
Glenn-Lewin, D. C., R. K. Peet and T. T. Veblen (1992)Plant succession. Theory and prediction. Chapman & Hall, London.
Hurd, L. E. and W. F. Fagan (1992) Cursorial spiders and succession: age or habitat structure?Oecologia 92: 215–221.
Kline, D. L. and R. C. Axtell (1977) Distribution ofCulicoildes hollensis, C. furens and C. bermudensis in relation to plant cover in North Carolina salt marsh (Diptera: Ceratopogonidsae).Journal Medical Entomology 13: 545–552.
Loertscher, M., A. Erhardt and J. Zettel (1995) Microdistribution of butterflies in mosaic-like habitat: The role of nectar sources.Ecography 18: 15–26.
MacMahon, J. A. (1981) Successional process comparison among biomes with special reference to probable roles of and influences on animals, pp. 277–304. In D. S. West, H. H. Shugart and D. B. Botkin (eds.)Forest succession: concept and application. Sprinter-Verlag, New York.
Maghon, G. J., D. V. Hagan, D. L. Kline and J. R. Linley (1990) Habitat characteristics and phenology of larvalCulicoides cf. virgop. (Diptera: Ceratopogonidae) from a coastal Georgia Salt Marsh.Environmental Entomology 19: 1068–1074.
Meyer, E. (1980) Aktivitättsdichte, Abundanz und Biomasse der Macrofauna. pp. 1–53.In H. Janetschek (ed.)Ökologische Untersuchungen an Wirbellosen des zentralalpinen hochgebirges 4. Obergurgl, Tirol.
Neumann, U. (1971) Die Sukzession der Bodenfauna (Carabidae [Coleoptera], Diplopoda und Isopoda) in den forstlich rekultivierten Gebieten des Rheinischen Braun-kohlenreviers.Pedobiologia 11: 193–226.
Niebylski, M. L. and G. B. Craig (1994) Dispersal and survival ofAedes albopistus at a scrap tire yard in Missouri.Journal American Mosquito Control Association 10: 339–343.
Odum, E. P. (1969) The strategy of ecosystem development.Science 1964: 262–270.
Pollet, M. (1992) Impact of environmental variables on the occurrence of Dolichopodid flies in marshland habitats in Belgium (Diptera: Dolichopodidae).Journal of Natural History 26: 621–636.
Pulliam, R. H. (1988) Sources, sinks, and population regulation.American Naturalist 132: 652–661.
Pulliam, R. H. and B. J. Danielson (1991) Souces, sinks, and habitat selection: a landscape perspective on population dynamics.American Naturalist, Supplement 137: 50–66.
Resetarits, W. J. Jr (1996) Oviposition site choice and life history evolution.American Zoologist 36: 205–215.
Rieb, J. P. and D. Guinier (1981) Analyse statistique de la distribution horizontale des larves deCulicoides (Dipteraes, Ceratopogonides) d’ un gite fluviatile.Bulletin d’Ecologie 12: 313–326.
Sowig, P. (1995) Habitat selection and offsprings survival rate in three paracoprid dung beetles: the influencesoil type and moisture.Ecography 18: 147–154.
Strenzke, K. (1950) Systematik, Morphologie und Ökologie der terrestrischen Chironomidaen.Archiv für Hydrobiologie, Supplement 18: 209–412.
Strüve-Kusenberg, R. (1981) Sukzesion und tropishe Structur der Bodenfauna von Brachlandlfächen.Pedobiologia 21: 132–141.
Tian, G., L. Brussard and B. T. Kang (1993) Biological effects of plant residues with contrasting chemical compositions under humid tropical conditions: effects on soil fauna.Soil Biology and Biochemistry 25: 731–737.
Verschoor, B. C. and B. P. M. Krebs (1995) Successional changes in saltmarsh carabid beetle (Coleoptera, Carabidae) community after embankment of the Markiezaat area.Pedobiologia 39: 385–404.
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Frouz, J. The effect of vegetation patterns on oviposition habitat preference: A driving mechanism in terrestrial chironomid (Diptera: Chironomidae) succession?. Res Popul Ecol 39, 207–213 (1997). https://doi.org/10.1007/BF02765267
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DOI: https://doi.org/10.1007/BF02765267