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RESEARCH & INTERPRETATION

Modern Biotechnology as an Integral Supplement to Conventional Plant Breeding

The Prospects and Challenges

USDA–ARS, Northern Crop Science Laboratory, Fargo, ND 58105

^* Corresponding author (prem.jauhar{at}ndsu.edu)

It would be an unsound fancy to expect that things which have never yet been done can be done except by methods which have never been tried.

—Sir Francis Bacon

The art of plant breeding was developed long before the laws of genetics became known. The advent of the principles of genetics at the turn of the last century catalyzed the growth of breeding, making it a science-based technology that has been instrumental in substantial improvements in crop plants. Largely through exploitation of hybrid vigor, grain yields of several cereal crops were substantially increased. Intervarietal and interspecific hybridizations, coupled with appropriate cytogenetic manipulations, proved useful in moving genes for resistance to diseases and insect pests from suitable alien donors into crop cultivars. Plant improvement has been further accelerated by biotechnological tools of gene transfer, to engineer new traits into plants that are very difficult to introduce by traditional breeding. The successful deployment of transgenic approaches to combat insect pests and diseases of important crops like rice (Oryza sativa L.), wheat (Triticum aestivum L.), maize (Zea mays L.), barley (Hordeum vulgare L.), and cotton (Gossypium hirsutum L.) is a remarkable accomplishment. Biofortification of crops constitutes another exciting development in tackling global hunger and malnutrition. Golden Rice, genetically enriched with vitamin A and iron, has, for example, the real potential of saving millions of lives. Yet another exciting application of transgenic technology is in the production of edible vaccines against deadly diseases. How these novel approaches to gene transfer can effectively supplement the conventional breeding programs is described. The current resistance to acceptance of this novel technology should be assessed and overcome so that its full potential in crop improvement can be realized.

Abbreviations: Bt, Bacillus thuringiensis • FHB, Fusarium head blight • fl-GISH, fluorescent genomic in situ hybridization • GM, genetically modified • PDR, pathogen-derived resistance • QPM, quality protein maize

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