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Spatial and temporal distribution of Tabanidae in the Pyrenees Mountains: the influence of altitude and landscape structure

Published online by Cambridge University Press:  25 April 2013

F. Baldacchino*
Affiliation:
Dynamique et Gouvernance des Systèmes Ecologiques, Centre d'Ecologie Fonctionnelle et Evolutive (CEFE), UMR 5175, Université Paul-Valéry (UM3), Montpellier, France
A. Porciani
Affiliation:
Dynamique et Gouvernance des Systèmes Ecologiques, Centre d'Ecologie Fonctionnelle et Evolutive (CEFE), UMR 5175, Université Paul-Valéry (UM3), Montpellier, France
C. Bernard
Affiliation:
Système d'Information Géographique en Ecologie, CEFE, Centre National de la Recherche Scientifique (CNRS), Montpellier, France
P. Jay-Robert
Affiliation:
Dynamique et Gouvernance des Systèmes Ecologiques, Centre d'Ecologie Fonctionnelle et Evolutive (CEFE), UMR 5175, Université Paul-Valéry (UM3), Montpellier, France
*
*Author for correspondence Phone: + 33 4 67 14 23 21 Fax: + 33 4 67 14 24 59 E-mail: frederic.baldacchino@cefe.cnrs.fr

Abstract

In high-altitude summer pastures, horseflies (Diptera: Tabanidae) can be a serious nuisance to livestock, as well as mechanical vectors of animal diseases such as besnoitiosis, an enzootic disease in the Pyrenees. However, the activity of horseflies in mountainous environments is poorly documented. To study the seasonality and distribution of tabanids in the Pyrenees Mountains, a sampling design was set up in two valleys on opposite sides of the mountain, one north-facing and one south-facing, along high-elevation gradients and at different distances from a water body between May and October 2011. The influence of the landscape on species richness and abundance was assessed by taking into account forested and unforested areas in 200 m radii around the trapping sites. Our findings indicated that: (1) The slope, the altitude and the size of unforested patches significantly influenced community composition of tabanids. (2) Altitude had a positive or a negative effect, depending on the species. (3) Species richness and abundance were negatively correlated with large open habitats and positively correlated with patch-shape complexity. (4) Seasonal succession of the most abundant species was observed in both valleys, with a maximum of catches at the beginning of August; however, tabanid activity ended earlier in the southern valley, which was more exposed to sunlight. (5) Philipomyia aprica, Tabanus bromius, Tabanus glaucopis and Hybomitra auripila were active from 9:00 to 19:00 h (GMT+1), with a peak of activity at midday. This paper also discusses the implications of these findings in relation to changes in horsefly distribution and their control in mountainous environments.

Type
Research Paper
Copyright
Copyright © Cambridge University Press 2013 

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References

Acapovi, G.L. (2001) Abondance relative des tabanidés dans la région des savanes de Côte d'Ivoire. Revue d’élevage et de médecine vétérinaire des pays tropicaux 54, 109114.Google Scholar
Altunsoy, F. & Kilic, A.Y. (2012) Seasonal abundance of horse fly (Diptera: Tabanidae) in Western Anatolia. Journal of the Entomological Research Society 14, 95105.Google Scholar
Andreeva, V.R., Kilic, A.Y. & Altunsoy, F. (2009) New contribution to information about Tabanidae (Diptera) adult and larvae from West Anatolia. Journal of the Entomological Research Society 11, 1930.Google Scholar
Andreyeva, R.V. (1982) On ecologo-morphological typing of tabanid larvae (Diptera, Tabanidae). Entomological Review 64, 4954.Google Scholar
Baldacchino, F., Cadier, J., Porciani, A., Buatois, B., Dormont, L. & Jay-Robert, P. (2012) Behavioural and electrophysiological responses of females of two species of tabanid to volatiles in urine of different mammals. Medical and Veterinary Entomology 27, 7785.Google Scholar
Barros, A.M. (2001) Seasonality and relative abundance of Tabanidae (Diptera) captured on horses in the Pantanal, Brazil. Memorias Do Instituto Oswaldo Cruz 96, 917923.CrossRefGoogle Scholar
Barros, A.T.M. & Foil, L.D. (2007) The influence of distance on movement of tabanids (Diptera: Tabanidae) between horses. Veterinary Parasitology 144, 380384.Google Scholar
Casasus, I., Sanz, A., Villalba, D., Ferrer, R. & Revilla, R. (2002) Factors affecting animal performance during the grazing season in a mountain cattle production system. Journal of Animal Science 80, 16381651.CrossRefGoogle Scholar
Chvála, M. (1979) Daily activity of Tabanidae in the Caucasus. Angewandte Parasitologie 20, 3845.Google Scholar
Chvála, M., Lyneborg, L. & Moucha, J. (1972) The Horse Flies of Europe (Diptera, Tabanidae). Copenhagen, Entomological Society of Copenhagen.Google Scholar
Colwell, R.K., Chao, A., Gotelli, N.J., Lin, S.Y., Mao, C.X., Chazdon, R.L. & Longino, J.T. (2012) Models and estimators linking individual-based and sample-based rarefaction, extrapolation and comparison of assemblages. Journal of Plant Ecology-UK 5, 321.Google Scholar
Cooksey, L.M. & Wright, R.E. (1987) Flight range and dispersal activity of the host-seeking horse fly, Tabanus abactor (Diptera, Tabanidae), in north central Oklahoma. Environmental Entomology 16, 211217.Google Scholar
Dolin, V.G. & Andreeva, R.V. (1983) Ecology and morphology of Tabanus infestus (Tabanidae). Parazitologiya 17, 304307.Google Scholar
Dusbabek, F. (1986) Composition and seasonal dynamics of the horse-flies fauna (Tabanidae) in a future flood region of Hnevkovice Dam Lake. Dipterologica Bohemoslovaca IV, 9193.Google Scholar
European Food Safety Authority (2010) Bovine Besnoitiosis: an emerging disease in Europe. EFSA Journal 8, 115.Google Scholar
Esteban, P., Ninyerola, M. & Prohom, M. (2009) Spatial modelling of air temperature and precipitation for Andorra (Pyrenees) from daily circulation patterns. Theoretical and Applied Climatology 96, 4356.Google Scholar
Ferreira-Keppler, R.L., Rafael, J.A. & Guerrero, J.C.H. (2010) Seasonality and landscape use by Tabanidae Species (Diptera) in the Central Amazon, Brazil. Neotropical Entomology 39, 645654.Google Scholar
Foil, L.D. (1989) Tabanids as vectors of disease agents. Parasitology Today 5, 8896.CrossRefGoogle ScholarPubMed
Foil, L.D. & Hogsette, J.A. (1994) Biology and control of tabanids, stable flies and horn flies. Revue Scientifique et Technique 13, 11251158.Google Scholar
Ganeva, D. (1999) Daily activity of Tabanus bromius L., Tabanus tergestinus Egg. and Haematopota pluvialis L. (Tabanidae, Diptera) in the Stara Zagora district. Periodicum Biologorum 101, 215220.Google Scholar
Gentile, A., Militerno, G., Schares, G., Nanni, A., Testoni, S., Bassi, P. & Gollnick, N.S. (2012) Evidence for bovine besnoitiosis being endemic in Italy-First in vitro isolation of Besnoitia besnoiti from cattle born in Italy. Veterinary Parasitology 184, 108115.Google Scholar
Gracia, M., Meghelli, N., Comas, L. & Retana, J. (2011) Land-cover changes in and around a National Park in a mountain landscape in the Pyrenees. Regional Environmental Change 11, 349358.CrossRefGoogle Scholar
Hackenberger, B.K., Jaric, D. & Krčmar, S. (2009) Distribution of tabanids (Diptera: Tabanidae) along a two-sided altitudinal transect. Environmental Entomology 38, 16001607.Google Scholar
Hammer, Ø., Harper, D.A.T. & Ryan, P.D. (2001) PAST: Paleontological Statistics software package for education and data analysis. Paleontologia Electronica 4, 29.Google Scholar
Harley, J.M.B. (1965) Seasonal abundance and diurnal variations in activity of some Stomoxys and Tabanidae in Uganda. Bulletin of Entomological Research 56, 319332.CrossRefGoogle ScholarPubMed
Haslett, J.R. (2001) Biodiversity and conservation of Diptera in heterogeneous land mosaics: a fly's eye view. Journal of Insect Conservation 5, 7175.Google Scholar
Hatfield, R.G. & LeBuhn, G. (2007) Patch and landscape factors shape community assemblage of bumble bees, Bombus spp. (Hymenoptera : Apidae), in montane meadows. Biological Conservation 139, 150158.Google Scholar
Hodkinson, I.D. (2005) Terrestrial insects along elevation gradients: species and community responses to altitude. Biological Reviews 80, 489513.Google Scholar
Hollander, A.L. & Wright, R.E. (1980) Daily activity cycles of 8 species of Oklahoma Tabanidae (Diptera). Environmental Entomology 9, 600604.CrossRefGoogle Scholar
Hughes, R.D., Duncan, P. & Dawson, J. (1981) Interactions between Camargue horses and horseflies (Diptera: Tabanidae). Bulletin of Entomological Research 71, 227242.Google Scholar
Hunter, M.D. (2002) Landscape structure, habitat fragmentation, and the ecology of insects. Agricultural and Forest Entomology 4, 159166.Google Scholar
Jacquiet, P., Lienard, E. & Franc, M. (2010) Bovine besnoitiosis: epidemiological and clinical aspects. Veterinary Parasitology 174, 3036.Google Scholar
Kilic, A.Y. (1993) A study on the seasonal activities of Tabanus bromius L., T. exclusus Pand., T. glaucopis Meig., T. spodopterus ponticus Ols., Mch., Chv., Philipomyia aprica (Meig). (Diptera: Tabanidae) in Eskisehir Region. Doga–Turkish Journal of Zoology 17, 303310.Google Scholar
Kingston, S.R., Wangberg, J.K. & Sanders, D.P. (1986) Flight behavior and nocturnal resting sites of Tabanus abactor Philip (Diptera, Tabanidae) in the Texas rolling plains. Journal of the Kansas Entomological Society 59, 337342.Google Scholar
Koerner, C. (2007) The use of ‘altitude’ in ecological research. Trends in Ecology and Evolution 22, 569574.Google Scholar
Konstantinov, S.A. (1993) The attack distance and the range and nature of the daily flight dispersion of horseflies in the genus Hybomitra (Diptera: Tabanidae). Parazitologiia 27, 419426.Google ScholarPubMed
Krčmar, S. (2005) Seasonal abundance of horse flies (Diptera: Tabanidae) from two locations in eastern Croatia. Journal of Vector Ecology 30, 316321.Google Scholar
Laveissiere, C. & Grebaut, P. (1990) Research on tsetse-fly traps (Diptera, Glossinidae) – development of an economic model, the Vavoua trap. Tropical Medicine and Parasitology 41, 185192.Google Scholar
Leclercq, M. (1971) Tabanidae (Diptera) des Basses-Alpes. Bulletin des Recherches Agronomiques de Gembloux 6, 424431.Google Scholar
Leclercq, M. (1977) Répartition en altitude des Tabanidae (Diptera) dans la province de Huesca (Pyrénées centrales espagnoles). Publicaciones del Centro pirenaico de Biologia Experimental 8, 6798.Google Scholar
McCoy, E.D. (1990) The distribution of insects along elevational gradients. Oikos 58, 313322.Google Scholar
McElligott, P.E.K. & Galloway, T.D. (1991) Daily activity patterns of horse flies (Diptera, Tabanidae, Hybomitra spp.) in northern and southern Manitoba. Canadian Entomologist 123, 371378.CrossRefGoogle Scholar
McElligott, P.E.K. & Lewis, D.J. (1998) Seasonal changes in abundance and gonotrophic age of host-seeking Tabanidae (Diptera) from a subarctic Labrador peatland. Journal of Medical Entomology 35, 763770.Google Scholar
Mihok, S. (2002) The development of a multipurpose trap (the Nzi) for tsetse and other biting flies. Bulletin of Entomological Research 92, 385403.Google Scholar
Mihok, S., Carlson, D.A., Krafsur, E.S. & Foil, L.D. (2006) Performance of the Nzi and other traps for biting flies in North America. Bulletin of Entomological Research 96, 387397.Google Scholar
Mullen, G.R. & Durden, L.A. (2002) Medical and Veterinary Entomology. Amsterdam, Academic Press.Google Scholar
Mullens, B.A. & Gerhardt, R.R. (1980) Faunal composition and seasonal distribution of tabanids in three geographic regions of eastern Tennessee (Diptera, Tabanidae). Proceedings of the Entomological Society of Washington 82, 4858.Google Scholar
Okiwelu, S.N. (1977) Observations on resting sites of Tabanidae in a Miombo woodland in Republic of Zambia. Journal of Medical Entomology 14, 195197.Google Scholar
Oliveira, A.F., Ferreira, R.L.M. & Rafael, J.A. (2007) Seasonality and diurnal activity of Tabanidae (Diptera : Insecta) of canopy in the adolpho ducke forested reserve, Manaus, Amazonas State, Brazil. Neotropical Entomology 36, 790797.Google Scholar
Pyke, G.H., Inouye, D.W. & Thomson, J.D. (2011) Activity and abundance of bumble bees near Crested Butte, Colorado: diel, seasonal, and elevation effects. Ecological Entomology 36, 511521.Google Scholar
Raymond, H.L. & Rousseau, F. (1987) Abundance of horse flies (Diptera, Tabanidae) and reactions of cattle in a traditional farm of French-Guiana. Acta Oecologica–Oecologia Applicata 8, 125134.Google Scholar
Roux, C., Masson, D., Bricaud, O., Coste, C. & Poumarat, S. (2011) Flore et végétation des lichens et champignons lichénicoles de quatre réserves naturelles des Pyrénées-Orientales (France). Bulletin de la Société Linneenne de Provence 14, 3151.Google Scholar
Sheppard, C. & Wilson, B.H. (1976) Flight range of Tabanidae in a Louisiana bottomland hardwood forest. Environmental Entomology 5, 752754.CrossRefGoogle Scholar
Sheppard, C. & Wilson, B.H. (1977) Relationship of horse fly host seeking activity to edge of wooded areas in southern Louisiana. Environmental Entomology 6, 781782.Google Scholar
ter Braak, J.F. & Smilauer, P. (2002) Canoco Reference Manual and Canodraw for Windows User's Guide: Software for Canonical Community Ordination (version 4.5). Ithaca, NY, USA, Microcomputer power.Google Scholar
Van Hennekeler, K., Jones, R.E., Skerratt, L.F., Fitzpatrick, L.A., Reid, S.A. & Bellis, G.A. (2008) A comparison of trapping methods for Tabanidae (Diptera) in North Queensland, Australia. Medical and Veterinary Entomology 22, 2631.Google Scholar
Van Hennekeler, K., Jones, R.E., Skerratt, L.F., Muzari, M.O. & Fitzpatrick, L.A. (2011) Meteorological effects on the daily activity patterns of tabanid biting flies in northern Queensland, Australia. Medical and Veterinary Entomology 25, 1724.CrossRefGoogle ScholarPubMed
Wardhaugh, K. (2005) Insecticidal activity of synthetic pyrethroids, organophosphates, insect growth regulators, and other livestock parasiticides: an Australian perspective. Environmental Toxicology and Chemistry 24, 789796.Google Scholar