Effect of volunteers on maize gene flow

Regulatory approvals for deliberate release of GM maize events into the environment have lead to real situations of coexistence between GM and non-GM, with some fields being cultivated with GM and conventional varieties in successive seasons. Given the common presence of volunteer plants in maize fields in temperate areas, we investigated the real impact of GM volunteers on the yield of 12 non-GM agricultural fields. Volunteer density varied from residual to around 10% of plants in the field and was largely reduced using certain cultural practices. Plant vigour was low, they rarely had cobs and produced pollen that cross-fertilized neighbour plants only at low—but variable—levels. In the worst-case scenario, the estimated content of GMO was 0.16%. The influence of GM volunteers was not enough to reach the 0.9% adventitious GM threshold but it could potentially contribute to adventitious GM levels, especially at high initial densities (i.e. above 1,000 volunteers/ha).

[1]  T. A. Kiesselbach The structure and reproduction of corn. 50th Anniversary Edition. , 1999 .

[2]  Dirk Reheul,et al.  The co-existence between transgenic and non-transgenic maize in the European Union: a focus on pollen flow and cross-fertilization. , 2005, Environmental biosafety research.

[3]  I. Broer,et al.  Coexistence Between GM and Non-GM Maize Crops – Tested in 2004 at the Field Scale Level (Erprobungsanbau 2004) , 2007 .

[4]  B. Ma,et al.  Extent of Cross‐Fertilization in Maize by Pollen from Neighboring Transgenic Hybrids , 2004 .

[5]  Chris Sauer,et al.  25th anniversary edition , 2010, J. Inf. Technol..

[6]  L Ej,et al.  agricultura, pesca y alimentación , 2008 .

[7]  S. Prat,et al.  A Specific Real-Time Quantitative PCR Detection System for Event MON810 in Maize YieldGard® Based on the 3′-Transgene Integration Sequence , 2003, Transgenic Research.

[8]  Teresa Esteve,et al.  Assessment of Real-time PCR Based Methods for Quantification of Pollen-mediated Gene Flow from GM to Conventional Maize in a Field Study , 2006, Transgenic Research.

[9]  J. H. Ford,et al.  Controlling Volunteer Corn (Zea mays) in Soybeans (Glycine max) with Diclofop and Glyphosate , 1982, Weed Science.

[10]  Marta Hernández,et al.  Development and comparison of four real-time polymerase chain reaction systems for specific detection and quantification of Zea mays L. , 2004, Journal of agricultural and food chemistry.

[11]  E. Stoller,et al.  Volunteer Corn (Zea mays) Interference in Soybeans (Glycine max) , 1988, Weed Science.

[12]  T. A. Kiesselbach The structure and reproduction of corn , 1980 .

[13]  A. Dietz-Pfeilstetter,et al.  Pollen-mediated intraspecific gene flow from herbicide resistant oilseed rape (Brassica napus L.) , 2007, Transgenic Research.

[14]  J. S. Brooks,et al.  Effectiveness of distance and border rows in preventing out-crossing in corn. , 1950 .

[15]  M. Bannert Simulation of transgenic pollen dispersal by use of different grain colour maize , 2006 .

[16]  G. Brookes,et al.  Genetically modified maize: pollen movement and crop co- existence , 2004 .

[17]  Enric Melé,et al.  Pollen-mediated gene flow in maize in real situations of coexistence. , 2006, Plant biotechnology journal.