Abstract
With the recent advent of genetic engineering, numerous genetically modified (GM) crops have been developed, and field planting has been initiated. In open-environment cultivation, the cross-pollination (CP) of GM crops with wild relatives, conventional crops, and organic crops can occur. This exchange of genetic material results in the gene flow phenomenon. Consequently, studies of gene flow among GM crops have primarily focused on the extent of CP between the pollen source plot and the adjacent recipient field. In the present study, Black Pearl Waxy Corn (a variety of purple glutinous maize) was used to simulate a GM-maize pollen source. The pollen recipient was Tainan No. 23 Corn (a variety of white glutinous maize). The CP rate (%) was calculated according to the xenia effect on kernel color. We assessed the suitability of common empirical models of pollen-mediated gene flow (PMGF) for GM maize, and the field border (FB) effect of the model was considered for small-scale farming systems in Asia. Field-scale data were used to construct an optimal model for maize PMGF in the maize-producing areas of Chiayi County, southern Taiwan (R.O.C). Moreover, each model was verified through simulation and by using the 95% percentile bootstrap confidence interval length. According to the results, a model incorporating both the distance from the source and the FB can have optimal fitting and predictive abilities.
Highlights
With improvements in biotechnology and genetic engineering, the area assigned to the cultivation of genetically modified (GM) crops has increased by 1.9 million hectares from 2017 to 2018 [1]
The average CP rate (%) in the row closest to the pollen source was 74.29% in the 2009-2A experiment, 36.12% in the 2009-2B experiment, 27.58% in the 2010–1 experiment, and 27.24% in the 2009–1 experiment. These results indicated that field border (FB) may enhance pollen exchange in the row of the pollen recipient closest to the pollen source
This study established a CP model for maize to describe the relationship between CP rate (%) and distance from a pollen source; this model was suitable at the field-scale level in southern Taiwan
Summary
With improvements in biotechnology and genetic engineering, the area assigned to the cultivation of genetically modified (GM) crops has increased by 1.9 million hectares from 2017 to 2018 [1]. More than 70% of plants produce offspring through cross-pollination (CP) between species; this is a commonly observed evolutionary phenomenon in plants, and pollen is the primary medium for this process [2]. Evaluating the model estimation of the extent of cross-pollination in maize.
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