Hostname: page-component-77c89778f8-vsgnj Total loading time: 0 Render date: 2024-07-20T11:59:46.488Z Has data issue: false hasContentIssue false
  • English
  • Français

A method to search for optimal field allocations of transgenic maize in the context of co-existence

Published online by Cambridge University Press:  16 April 2008

Yann Devos ,
Mathias Cougnon ,
Olivier Thas  and
Dirk Reheul
Yann Devos
Affiliation:
Department of Plant Production, Faculty of Bioscience Engineering, Ghent University, Coupure Links 653, 9000 Ghent, Belgium
Mathias Cougnon
Affiliation:
Department of Plant Production, Faculty of Bioscience Engineering, Ghent University, Coupure Links 653, 9000 Ghent, Belgium
Olivier Thas
Affiliation:
Department of Applied Mathematics, Biometrics and Process Control, Faculty of Bioscience Engineering, Ghent University, Coupure Links 653, 9000 Ghent, Belgium
Dirk Reheul
Affiliation:
Department of Plant Production, Faculty of Bioscience Engineering, Ghent University, Coupure Links 653, 9000 Ghent, Belgium

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Spatially isolating genetically modified (GM) maize fields from non-GM maize fields is a robust on-farm measure to keep the adventitious presence of GM material in the harvest of neighboring fields due to cross-fertilizations below the European labeling threshold of 0.9%. However, the implementation of mandatory and rigid isolation perimeters can affect the farmers' freedom of choice to grow GM maize on their fields if neighboring farmers do not concur with their respective cropping intentions and crop plans. To minimize the presence of non-GM maize within isolation perimeters implemented around GM maize fields, a method was developed for optimally allocating GM maize to a particular set of fields. Using a Geographic Information System dataset and Monte Carlo analyses, three scenarios were tested in a maize cultivation area with a low maize share in Flanders (Belgium). It was assumed that some farmers would act in collaboration by sharing the allocation of all their arable land for the cultivation of GM maize. From the large number of possible allocations of GM maize to any field of the shared pool of arable land, the best field combinations were selected. Compared to a random allocation of GM maize, the best field combinations made it possible to reduce spatial co-existence problems, since at least two times less non-GM maize fields and their corresponding farmers occurred within the implemented isolation perimeters. In the selected field sets, the mean field size was always larger than the mean field size of the common pool of arable land. These preliminary data confirm that the optimal allocation of GM maize over the landscape might theoretically be a valuable option to facilitate the implementation of rigid isolation perimeters imposed by law.


Keywords

adventitious mixingco-existencecross-fertilizationfield allocationgenetically modified cropsisolation perimeterssimulations
Type
Research Article
Information
Environmental Biosafety Research , Volume 7 , Issue 2 , April 2008 , pp. 97 - 104
Copyright
© ISBR, EDP Sciences, 2008

References

Bannert, M, Stamp, P (2007) Cross-pollination of maize at long distance. Eur. J. Agron. 27: 4451 CrossRef
Beckmann, V, Soregaroli, C, Wesseler, J (2006) Coexistence rules and regulations in the European Union. Amer. J. Agr. Econ. 88: 11931199 CrossRef
Bock A-K, Lheureux K, Libeau-Dulos M, Nilsagård H, Rodríguez-Cerezo E (2002) Scenarios for co-existence of genetically modified, conventional and organic crops in European agriculture. http://ftp.jrc.es/eur20394en.pdf
Castellazzi, MS, Perry, JN, Colbach, N, Monod, H, Adamczyk, K, Viaud, V, Conrad, KF (2007) New measures and tests of temporal and spatial pattern of crops in agricultural landscapes. Agric. Ecosyst. Environ. 118: 339349 CrossRef
De Schrijver, A, Devos, Y, Van den Bulcke, M, Cadot, P, De Loose, M, Reheul, D, Sneyers, M (2007) Risk assessment of GM stacked events obtained from crosses between GM events. Trends Food Sci. Technol. 18: 101109 CrossRef
Della Porta, G, Ederle, D, Bucchini, L, Prandi, M, Verderio, A, Pozzi, C (2008) Maize pollen mediated gene flow in the Po valley (Italy): source-recipient distance and effect of flowering time. Eur. J. Agron. 28: 255265 CrossRef
Demont, M, Daems, W, Dillen, K, Mathijs, E, Sausse, C, Tollens E (2008) Regulating coexistence in Europe: Beware of the domino-effect! Ecol. Econ. 64: 683689 CrossRef
Devos, Y, Reheul, D, De Schrijver A (2005) The co-existence between transgenic and non-transgenic maize in the European Union: a focus on pollen flow and cross-fertilization. Environ. Biosafety Res. 4: 7187 CrossRef
Devos Y, Cougnon M, Thas O, De Clercq EM, Reheul D (2007a) Recommendations to facilitate the implementation of isolation perimeters. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 287–288
Devos, Y, Reheul, D, Thas, O, De Clercq, EM, Cougnon, M, Cordemans, K (2007b) Implementing isolation perimeters around genetically modified maize fields. Agron. Sustain. Dev. 27: 155165 CrossRef
Devos Y, Thas O, Cougnon M, De Clercq EM, Cordemans K, Reheul D (2008) Feasibility of isolation perimeters for genetically modified maize. Agron. Sustain. Dev., DOI:10.1051/agro:2007031
Dolezel M, Pascher K, Grabherr G (2005) Regionality as a key parameter for co-existence of genetically modified maize with conventional and organic maize. In Messéan A, ed, Proceedings of the 2nd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, Agropolis Productions, Montpellier, pp 203–206
EC (2003a) Commission Recommendation of 23 July 2003 on guidelines for the development of national strategies and best practices to ensure the coexistence of genetically modified crops with conventional and organic farming. Official J. European Comm. L 189: 3647
EC (2003b) Regulation (EC) 1829/2003 of the European Parliament and of the Council of 22 September 2003 on genetically modified food and feed. Official J. European Comm. L 268: 1–23
EC (2006) Report on the implementation of national measures on the co-existence of genetically modified crops with conventional and organic farming. http://ec.europa.eu/agriculture/coexistence/sec313_en.pdf
Ganz C, Struzyna-Schulze C, Eder J, Holz F, Schmidt K, Broer I (2007) “Erprobungsanbau 2005”: Different crops as spacers to minimize cross fertilization between GM and non-GM maize on field scale level. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 267–268
Goggi, AS, Caragea, P, Lopez-Sanchez, H, Westgate, M, Arritt, R, Clark, C (2006) Statistical analysis of outcrossing between adjacent maize grain production fields. Field Crop Res. 99: 147157 CrossRef
Gustafson, DI, Brants, IO, Horak, MJ, Remund, KM, Rosenbaum, EW, Soteres, JK (2006) Empirical modeling of genetically modified maize grain production practices to achieve European Union labeling thresholds. Crop Sci. 46: 21332140 CrossRef
Hüsken A, Schiemann J (2007) Impact of silage maize (Zea mays L.) on GMO quantification and coexistence. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 357–358
Hüsken A, Ammann K, Messeguer J, Papa R, Robson P, Schiemann J, Squire G, Stamp P, Sweet J, Wilhelm R (2007) A major European synthesis of data on pollen and seed mediated gene flow in maize in the SIGMEA project. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 53–56
Kraic J, Mihalčík P, Singer M, Plačková A (2007) Coexistence of genetically modified and conventional maize: practical experience on-farm in Slovakia. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 251–252
Lécroart B, Gauffreteau A, Le Bail M, Leclaire M, Messéan A (2007) Coexistence of GM and non-GM maize: effect of regional structural variables on GM dissemination risk. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 115–118
Lipsius, K, Wilhelm, R, Richter, O, Schmalstieg, KJ, Schiemann, J (2006) Meteorological input data requirements to predict cross-pollination of GM maize with Lagrangian approaches. Environ. Biosafety Res. 5: 151168 CrossRef
Marvier, M (2008) Pharmaceutical crops in California, benefits and risks. A review. Agron. Sustain. Dev. 28: 19 CrossRef
Mazzoncini M, Balducci E, Gorelli S, Russu R, Brunori G (2007) Coexistence scenarios between GM and GM-free corn in Tuscany region (Italy). In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 295–296
Messéan A, Angevin F (2007) Coexistence measures for maize cultivation: lessons from gene flow and modeling studies. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 23–26
Messéan A, Angevin F, Gómez-Barbero M, Menrad K, Rodríguez-Cerezo E (2006) New case studies on the coexistence of GM and non-GM crops in European agriculture. http://ftp.jrc.es/eur22102en.pdf
Messeguer, J, Peñas, G, Ballester, J, Bas, M, Serra, J, Salvia, J, Palaudelmàs, M, Melé, E (2006) Pollen-mediated gene flow in maize in real situations of coexistence. Plant Biotechnology J. 4: 633645 CrossRef
Messeguer J, Palaudelmàs M, Peñas G, Serra J, Salvia J, Ballester J, Bas M, Pla M, Nadal A, Melé E (2007) Three year study of a real situation of co-existence in maize. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 93–96
NIS (2008) Landbouwtelling 2007. http://www.statbel.fgov.be/downloads/cah2007mprov_nl.xls
Palaudelmàs M, Messeguer J, Peñas G, Serra J, Salvia J, Pla M, Nadal A, Melé E (2007) Effect of sowing and flowering dates on maize gene flow. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 235–236
Perry, JN (2002) Sensitive dependencies and separation distances for genetically modified herbicide-tolerant crops. Proc. R. Soc. Lon. B 269: 11731176 CrossRef
Pla, M, La Paz, J-L, Peñas, G, García, N, Palaudelmàs, M, Esteve, T, Messeguer, J, Melé, E (2006) Assessment of real-time PCR based methods for quantification of pollen-mediated gene flow from GM to conventional maize in a field study. Transgenic Res. 15: 219228 CrossRef
Sanvido O, Widmer F, Winzeler M, Streit B, Szerencsits E, Bigler F (2008) Definition and feasibility of isolation distances for transgenic maize. Transgenic Res., DOI:10.1007/s11248-007-9103-1
Schiemann, J (2003) Co-existence of genetically modified crops with conventional and organic farming. Environ. Biosafety Res. 2: 213217 CrossRef
Sicard G (2003) Management of varietal purity in seed production in France: organization and cost. In Boelt B, ed, Proceedings of the 1st European Conference on the Co-existence of Genetically Modified Crops with Conventional and Organic Crops, Danish Institute of Agricultural Sciences, Research Centre Flakkebjerg, pp 57–59
van de Wiel, CCM, Lotz, LAP (2006) Outcrossing and coexistence of genetically modified with (genetically) unmodified crops: a case study of the situation in the Netherlands. Neth. J. Agr. Sci. 54: 1735
van de Wiel CCM, Dolstra O, Thissen JTNM, Groeneveld RMW, Kok EJ, Scholtens IMJ, Smulders MJM, Lotz LAP (2007) Pollen-mediated gene flow in maize under agronomical conditions representative for the Netherlands. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 269–270
Viaud V, Monod H, Lavigne C, Angevin F, Adamczyk K (2007) Spatial sensitivity of maize gene flow to landscape patterns: a simulation approach. In Stein AJ, Rodríguez-Cerezo E, eds, Book of abstracts of the 3rd International Conference on Coexistence between Genetically Modified (GM) and non-GM-based Agricultural Supply Chains, European Commission, Spain, pp 123–126
Weber, WE, Bringezu, T, Broer, I, Holz, F, Eder, J (2007) Coexistence between GM and non-GM maize crops – tested in 2004 at the field scale level (Erprobungsanbau 2004). J. Agron. Crop Sci. 193: 7992 CrossRef
Weekes, R, Allnutt, T, Boffey, C, Morgan, S, Bilton, M, Daniels, R, Henry, C (2007) A study of crop-to-crop gene flow using farm scale sites of fodder maize (Zea mays L.) in the UK. Transgenic Res. 16: 203211 CrossRef