Three years analysis of Lobesia botrana (Lepidoptera: Tortricidae) flight activity in a quarantined area

Sione, Walter

doi:10.48311/jcp.2015.1242

Three years analysis of Lobesia botrana (Lepidoptera: Tortricidae) flight activity in a quarantined area

10.48311/jcp.2015.1242

Volume 4, Issue 5
December 2015

Pages 605-615

Author

W. Sione

Autonomous University of Entre Ríos, Regional Center for Geomatics, Matteri y España s/n, Diamante, Entre Ríos, Argentina.

Abstract

Lobesia botrana (Denis & Schiffermüller) (Lepidoptera: Tortricidae), is an important vineyard-pest in the European and Mediterranean areas and it was recently described in Argentina and Chile. Since knowledge on the L. botrana phenology on Argentina is still limited, the objective of this study was to develop a phenological model to predict voltinism of L. botrana in Argentina through a regional approach.Voltinism of L. botrana males was simulated based on occurrence of four non-overlapping flights. Nonlinear regression models were constructed using the weekly average trap catches from the agricultural seasons 2011-2012 to 2013-2014 and amount of degree-days accumulation. Weibull equation showed, on average for the four annual flights, the best estimate of the observed variability in the percentage of adult catches in relation to degree-day accumulation. It can be expected that 50% of male adult emergence for the first flight occurs at 443.9 DD; in the second flight at 1211.7 DD; while in the third and the fourth flights, the accumulation of degree days reaches values of 2077.8 DD and 2905 DD, respectively. The regional approach adopted in this work could explainthe variation found in field data and has a reasonable predictive and explicative capability as a component in the ongoing prospective analysis of the activity of L. botrana in Argentina.

Keywords

Lobesia botrana

surveillance system

voltinism

20.1001.1.22519041.2015.4.5.5.5

Aalto, J., Pirinen, P., Heikkinen, J. and Venäläinen, A. 2013.Spatial interpolation of monthly climate data for Finland, comparing the performance of kriging and generalized additive models. Theoretical and Applied Climatology, 112: 99-111.

Ali, M. and Abustan, I. 2014. A new novel index for evaluating model performance. Journal of Natural Resources and Development, 4: 1-9.

Amo-Salas, M., Ortega-López, V., Harman, R. and Alonso-González, A. 2001. A new model for predicting the flight activity of Lobesia botrana (Lepidoptera: Tortricidae). Crop Protection, 30: 1586-1593.

Armendáriz, I., Campillo, G., Pérez Sanz, A., Capilla, C., Juárez, S. and Miranda, L.2007. La polilla del racimo Lobesia botrana en la D. O. Arribes, años 2004 a 2006. Boletín de Sanidad Vegetal-Plagas, 33: 477-489.

Armendáriz, I., Pérez Sanz, A., Capilla, C., Juárez, S., Miranda, L., Nicolás, J. and Aparicio, E. 2009. Cinco años de seguimiento de la polilla del racimo de la vid Lobesia botrana en la D.O. Arribes Castilla y León, España. Boletín de Sanidad Vegetal-Plagas, 35: 193-204.

Baskerville, G. and Emin, P. 1969.Rapid estimation of heat accumulation from maximum and minimum temperatures. Ecology, 50: 515-517.

Blanco, P., Sione, W., Hardtke, L., del Valle, H., Aceñolaza, P., Zamboni, P., Heit, G., Cortese, P. and Moschini, R. 2010. Estimación espacial de variables climáticas en el territorio argentino mediante el uso de software libre. XIV Symposia InternationalSelper, Guanajuato, México. s/p.

Briere, J. F. and Pacros, P. 1998. Comparison of temperature-dependent growth models with the development of Lobesia botrana (Lepidoptera, Tortricidae). Environmental Entomology, 27: 94-101.

Caffarelli, V. and Vita, G.. 1988. Heat accumulation for timing grapevine moth control measures. Bulletin SROP, 11: 24-26.

Dalla Monta, L., Marchesini, E. and Pavan, F. 2007. Relationship between grape berry moths and grey mould. Informe Fitopatológico, 57:28-35.

Damos, P. andSavopoulou-Soultani, M. 2012. Temperature-driven models for insect development and vital thermal requirements. Psyche, 2012:1-13.

Damos, P. and Savopoulou Soultani, M. 2010. Development and statistical evaluation of models in forecasting moth phenology of major lepidopterous peach pest complex for Integrated Pest Management programs. Crop Protection, 29: 1190-1199.

Degaetano, A. and Belcher, B. 2006. Spatial interpolation of daily maximum and minimum air temperature based on meteorological model analyses and independent observations. Journal of Applied Meteorology and Climatology, 46: 1981-1992.

Delbac, L., Lecharpentier, P. and Thiery, D. 2010. Larval instars determination for the European grapevine moth Lepidoptera: Tortricidae based on the frequency distribution of head-capsule widths. Crop Protection, 29: 623-630.

del Tío, R., Martínez, J., Ocete, R. and Ocete, M. 2001. Study of the relationship between sex pheromone trap catches of Lobesia botrana Denis y Schiffermüller (Lep., Tortricidae) and the accumulation of degree-days in Sherry vineyards SW of Spain. Journal of Applied Entomology, 133: 626-632.

Di Rienzo, J., Casanoves, F., Balzarini, M., Gonzalez, L., Tablada, M. and Robledo, C. 2013.InfoStat versión 2013, Grupo InfoStat, FCA, Universidad Nacional de Córdoba, Argentina. Available at http//www.infostat.com. ar (accessed March, 2013).

Dodson, R. and Marks, D. 1997. Daily air temperature interpolated at high spatial resolution over a large mountainous region. Climate Research, 8: 1-20.

Dos Santos, M. And Porta Nova, A. 2007.Estimating and Validating Nonlinear Regression Metamodels in Simulation. Communications in Statistics-Simulation and Computation, 36: 123-137.

Gallardo, A.,Ocete, R., López, M., Maistrello, L., Ortega, F., Semedo, A. and Soria, F. 2009. Forecasting the flight activity of Lobesia botrana Denis y Schiffermüller (Lepidoptera, Tortricidae) in Southwestern Spain. Journal of Applied Entomology, 133: 626-632.

González, M. 2010. Lobesia botrana, polilla de la uva. Revista de Enología, 2: 2-5.

Gutierrez, A., Ponti, L., Cooper, M., Gilioli, G., Baumgärtner, J. and Duso, C. 2012. Prospective analysis of the invasive potential of the European grapevine moth Lobesia botranaDenis y Schiffermüller. in California. Agricultural and Forest Entomology, 14: 225-238.

Haylock, M.,Hofstra, N., Klein Tank,A., Klok, E., Jones, P. and New, M. 2008. A European daily high-resolution gridded data set of surface temperature and precipitation for 1950-2006. Journal of Geophysical Research, 113: 1-12.

Heit, G., Sione, W. and Cortese, P. 2014. Comparación de modelos termodependientes aplicados al voltinismo de Lobesia botrana: un análisis a escala regional. SNS, 3: 9-17.

Ioriatti, C., Anfora, G., Tasin,M., de Cristofaro, A., Witzgall, P. and Luchi, A. 2011. Chemical Ecology and Management of Lobesia botrana Lepidoptera: Tortricidae. Journal of Economical Entomology, 1044: 1125-1137.

Jan Wagenmakers, E. and Farrell, S. 2004. AIC model selection using Akaike weights. Psychonomic Bulletin & Review, 11: 192-196.

Kumral, N., Kovanci, B. and Akbudak, B. 2005. Pheromone trap catches of the olive moth, Prays oleae Bern. (Lep., Plutellidae) in relation to olive phenology and degree-day models. Journal of Applied Entomology, 129: 375-381.

McMeekin, T. A., Olley, J., Ross T. and Ratkowsky, D. A. 1993. Predictive Microbiology: Theory and Application. Research Studies Press, Taunton. UK.

MartinVertedor, D., Ferrero-Garcia, J. and Torres Vila, L. 2010.Global warming affects phenology and voltinism of Lobesia botrana in Spain. Agricultural and Forest Entomology, 12: 169-176.

Maurer, E. and Hidalgo, H. 2008. Utility of daily vs. monthly large-scale climate data: an intercomparison of two statistical downscaling methods. Hydrology and Earth System Sciences, 12: 551-563.

Milonas, P.,SavopoulouSoultani, M. and Stavridis, D. 2001.Day-degree models for predicting the generation time and fight activity of local populations of Lobesia botrana(Denis & schiffermüller) (Lepidoptera: Tortricidae)in Greece. Journal of Applied Entomology, 125: 515-518.

Milonas, P. and SavapoulouSoultani, M. 2006. Seasonal abundance and population dynamics of Adoxophyesorana (Lepidoptera, Tortricidae) in Northern Greece. International Journal of Pest Management, 52: 45-51.

Moravie, M., Davison, A., Pasquier, D. and Charmillot, P.2006. Bayesian forecasting of grape moth emergence. Ecological Modeling, 197: 478-489.

Pavan, F., Floreani, C., Barro, P., Zandigiacomo, P. and Dalla Monta, L. 2010. Influence of Generation and Photoperiod on Larval Development of Lobesia botrana (Lepidoptera: Tortricidae). Environmental Entomology, 39: 1652-1658.

Pavan, F., Zandigiacomo, P. and Dalla Monta, L. 2006. Influence of the grape-growing area on the phenology of Lobesia botrana second generation. Bulletin of Insectology, 59: 105-109.

Quantum GIS Development Team 2013. Quantum GIS Geographic Information System. Open Source Geospatial Foundation Project. Available at http://qgis.osgeo.org (accessed January, 2013).

Quinn, P. and Keough, M. 2002. Experimental Design and Data Analysis for Biologist. Cambridge University Press, Cambridge. UK.

R Core Team. 2012. R, A language and environment for statistical computing, R Foundation for Statistical Computing, Vienna, Austria Available at http//www.R-project.org (accessed January, 2013).

Rakefet, S., Zahavi, T., Soroker, V. and Harari, A. 2009. The effect of grape vine cultivars on Lobesia botrana (Lepidoptera: Tortricidae) population levels. Journal of Pest Science, 82: 187-193

RanjbarAghdam, H., Fathipour, Y. and Kontodimas, D. 2011. Evaluation of non-linear models to describe development and fertility of codling moth (Lepidoptera, Tortricidae) at constant temperatures. Entomologia Hellenica, 20: 3-16.

Rock, G.,Stinner, R., Bacheler, J., Hull, L. and Hogmire, H.1993. Predicting geographical and within-season variation in male flights of four fruit pests. Environmental Entomology, 22: 716-725.

Satake, A., Ohgushi, T., Urano, S. and Uchimura, K. 2006. Modeling population dynamics of a tea pest with temperature-dependent development, Predicting emergence timing and potential damage. Ecology Research, 21: 107-116.

Sciarretta, A., Zinni, A., Mazzocchetti, A. and Trematerra, P. 2008. Spatial analysis of Lobesia botrana (Lepidoptera: Tortricidae) Male population in a Mediterranean agricultural landscape in central Italy. Environmental Entomology, 372: 382-390.

Stahl, K., Moore, R., Floyer, J., Asplin,M. and McKendry, I. 2006. Comparison of approaches for spatial interpolation of daily air temperature in a large region with complex topography and highly variable station density. Agricultural and Forest Meteorology, 139: 224-236.

Stefanos, S., Panagiotis, G. and Savopoulou-Soultani, M. 2005. Cold hardiness of diapausing and non-diapausing pupae of the European grapevine moth, Lobesia botrana. Entomologia Experimentalis et Applicata, 117: 113-118.

Thiéry, D. and Moreau, J. 2005. Relative performance of European grapevine moth Lobesia botrana on grapes and other hosts. Oecologia, 143: 548-557.

Tobin, P., Nagarkatti, S. and Saunders, M. 2003. Phenology of grape berry moth Lepidoptera, Tortricidae in cultivated grape at selected geographic locations. Environmental Entomology, 32: 340-346.

Zwietering, M., Jongenburger, I., Romboust, F. and Van’tRiet, K. 1990. Modeling of the bacterial growth curve. Applied Environmental Microbiology, 56: 1875-1881.

XML

PDF 403.77 K