Temperature effects on pitfall catches of epigeal arthropods: a model and method for bias correction
Status PubMed-not-MEDLINE Jazyk angličtina Země Velká Británie, Anglie Médium print-electronic
Typ dokumentu časopisecké články
PubMed
23539634
PubMed Central
PMC3607414
DOI
10.1111/1365-2664.12023
Knihovny.cz E-zdroje
- Klíčová slova
- Arrhenius equation, Carabidae, activity-density, differencing, meta-analysis, model estimation, monitoring, pitfall traps,
- Publikační typ
- časopisecké články MeSH
Carabids and other epigeal arthropods make important contributions to biodiversity, food webs and biocontrol of invertebrate pests and weeds. Pitfall trapping is widely used for sampling carabid populations, but this technique yields biased estimates of abundance ('activity-density') because individual activity - which is affected by climatic factors - affects the rate of catch. To date, the impact of temperature on pitfall catches, while suspected to be large, has not been quantified, and no method is available to account for it. This lack of knowledge and the unavailability of a method for bias correction affect the confidence that can be placed on results of ecological field studies based on pitfall data.Here, we develop a simple model for the effect of temperature, assuming a constant proportional change in the rate of catch per °C change in temperature, r, consistent with an exponential Q10 response to temperature. We fit this model to 38 time series of pitfall catches and accompanying temperature records from the literature, using first differences and other detrending methods to account for seasonality. We use meta-analysis to assess consistency of the estimated parameter r among studies.The mean rate of increase in total catch across data sets was 0·0863 ± 0·0058 per °C of maximum temperature and 0·0497 ± 0·0107 per °C of minimum temperature. Multiple regression analyses of 19 data sets showed that temperature is the key climatic variable affecting total catch. Relationships between temperature and catch were also identified at species level. Correction for temperature bias had substantial effects on seasonal trends of carabid catches.Synthesis and Applications. The effect of temperature on pitfall catches is shown here to be substantial and worthy of consideration when interpreting results of pitfall trapping. The exponential model can be used both for effect estimation and for bias correction of observed data. Correcting for temperature-related trapping bias is straightforward and enables population estimates to be more comparable. It may thus improve data interpretation in ecological, conservation and monitoring studies, and assist in better management and conservation of habitats and ecosystem services. Nevertheless, field ecologists should remain vigilant for other sources of bias.
Zobrazit více v PubMed
Atienza, J.C. , Farinós, G.P. & Zaballos, J.P. (1996) Role of temperature in habitat selection and activity patterns in ground beetle Angoleus nitidus. Pedobiologia, 40, 240–250.
Baars, M.A. (1979) Patterns of movement of radioactive carabid beetles. Oecologia, 44, 125–140. PubMed
Bohan, D.A. , Boursault, A. , Brooks, D.R. & Petit, S. (2011) National‐scale regulation of the weed seedbank by carabid predators. Journal of Applied Ecology, 48, 888–898.
Briers, R.A. , Carsiss, H.M. & Gee, J.H.R. (2003) Flight activity of adult stoneflies in relation to weather. Ecological Entomology, 28, 31–40.
Cormac, R.M. & Ord, J.K. (1979) Spatial and temporal analysis in ecology. International Co‐operative Publishing House, Fairland, USA.
Crawley, M.J. (2005) Statistics: An Introduction using R. John Wiley and Sons, New York, USA.
Crist, T.O. & Ahern, G. (1999) Effects of habitat patch size and temperature on the distribution and abundance of ground beetles (Coleoptera: Carabidae) in an old field. Environmental Entomology, 28, 681–689.
Dempster, J.P. (1967) The control of Pieris rapae with DDT. I. The natural mortality of the young stages of Pieris. Journal of Applied Ecology, 4, 485–500.
Hatten, T.D. , Bosque‐Perez, N.A. , Johnson‐Maynard, J. & Eigenbrode, S.D. (2007) Tillage differentially affects the capture rate of pitfall traps for three species of carabid beetles. Entomologia Experimentalis et Applicata, 124, 177–187.
Hemerik, L. & Brussaard, L. (2002) Diversity of soil macro‐invertebrates in grasslands under restoration succession. European Journal of Soil Biology, 38, 145–150.
Heydemann, B. (1953) Agrarökologische Problematik. Ph.D. thesis, University of Kiel.
Holland, J.M. (2002) The agroecology of carabid beetles. Intercept, Andover, UK.
Honek, A. (1988) The effect of crop density and microclimate on pitfall trap catches of Carabidae, Staphylinidae (Coleoptera), and Lycosidae (Araneae) in cereal fields. Pedobiologia, 32, 233–242.
Honek, A. (1997a) The effect of plant cover and weather on the activity density of ground surface arthropods in a fallow field. Biological Agriculture and Horticulture, 15, 203–210.
Honek, A. (1997b) The effect of temperature on the activity of Carabidae (Coleoptera) in a fallow field. European Journal of Entomology, 94, 97–104.
Johnson, C.G. (1969) Migration and Dispersal of Insects by Flight. Methuen, London, UK.
Jones, M.G. (1976) The arthropod fauna of a winter wheat field. Journal of Applied Ecology, 13, 61–85.
Kegel, B. (1990) Diurnal activity of carabid beetles living on arable land The Role of Ground Beetles in Ecological and Environmental Studies (ed. Stork N.), pp. 65–76. Intercept, Andover, UK.
Kotze, D.J. , Brandmayr, P. , Casale, A. , Duffy‐Richard, E. , Dekoninck, W. , Koivula, M.J. , Lövei, G.L. , Mossakowski, D. , Noordijk, J. , Paarmann, W. , Pizzolotto, R. , Saska, P. , Schwerk, A. , Serrano, J. , Szyszko, J. , Taboada, A. , Turin, H. , Venn, S. , Vermeulen, R. & Zetto, T. (2011) Forty years of carabid beetle research in Europe ‐ from taxonomy, biology, ecology and population studies to bioindication, habitat assessment and conservation. Zookeys, 100, 55–148. PubMed PMC
Kromp, B. (1999) Carabid beetles in sustainable agriculture: a review on pest control efficacy, cultivation impacts and enhancement. Agriculture, Ecosystems and Environment, 74, 187–228.
Larochelle, A. & Larivière, M.C. (2003) A Natural History of the Ground‐Beetles (Coleoptera: Carabidae) of America North of Mexico. Pensoft, Sofia, BG.
Leslie, T.W. , Hoheisel, G.A. , Biddinger, D.J. , Rohr, J.R. & Fleischer, S.J. (2007) Transgenes sustain epigeal insect biodiversity in diversified vegetable farm systems. Environmental Entomology, 36, 234–244. PubMed
Logan, J.A. , Wollkind, D.J. , Hoyt, S.C. & Tanigoshi, L.K. (1976) An analytic model for description of temperature dependent rate phenomena in arthropods. Environmental Entomology, 5, 1133–1140.
Luff, M.L. (1978) Diel activity patterns of some field Carabidae. Ecological Entomology, 3, 53–62.
Madden, L.V. & Paul, P.A. (2011) Meta‐analysis for evidence synthesis in plant pathology: an overview. Phytopathology, 101, 16–30. PubMed
Messenger, P.S. (1959) Bioclimatic studies with insects. Annual Review of Entomology, 4, 183–206.
Mitchell, B. (1963) Ecology of two carabid beetles, Bembidion lampros (Herbst) and Trechus quadristriatus (Schrank) 2. Studies on populations of adults in the field, with special reference to the technique of pitfall trapping. Journal of Animal Ecology, 32, 377–392.
R Development Core Team (2010) R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria: Available at: http://www.R-project.org/.
Rosenberg, M.S. , Adams, D.C. & Gurevitch, J. (2000) MetaWin: statistical software for Meta‐Analysis version 2.0, Sinauer Associates, Inc, Sunderland, USA.
Rosenberg, M.S. , Garrett, K.A. , Su, Z. & Bowden, R.L. (2004) Meta‐analysis in plant pathology: synthesizing research results. Phytopathology, 94, 1013–1017. PubMed
Shumway, R.H. & Stoffer, D.S. (2006) Time Series Analysis and Its Applications With R Examples. Springer Science + Business Media, New York, USA.
Southwood, T.R.E. & Henderson, P.A. (2000) Ecological Methods, 3rd edn. Blackwell Science, Oxford, UK.
Taylor, L.R. (1963) Analysis of the effect of temperature on insects in flight. Journal of Animal Ecology, 32, 99–117.
Thiele, H.‐U. (1977) Carabid Beetles in Their Environments. Springer‐Verlag, Berlin.
Wallin, H. & Ekbom, B. (1994) Influence of hunger level and prey densities on movement patterns in three species of Pterostichus beetles (Coleoptera: Carabidae). Environmental Entomology, 23, 1171–1181.
Wautier, V. (1971) Un phénomèn social chez les Coléoptères: le grégarisme des Brachinus (Caraboidea Brachinidae). Insectes Sociaux, 18 (3 bis), 1–84.
Williams, C.B. (1940) An analysis of four years captures of insects in a light trap. Part II. The effect of weather conditions on insect activity; and the estimation and forecasting of changes in the insect population. Transactions of the Royal Entomological Society of London, 90, 227–306.
