Overview
- Editors:
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Ronald L. Phillips
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Department of Agronomy and Plant Genetics, University of Minnesota, St. Paul, USA
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Indra K. Vasil
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Laboratory of Plant Cell and Molecular Biology, University of Florida, Gainesville, USA
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Table of contents (26 chapters)
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- Jeffrey L. Bennetzen, Vaidyanathan Subramanian, Jichen Xu, Shanmukhaswami S. Salimath, Sujatha Subramanian, Dinakar Bhattramakki et al.
Pages 347-355
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- Randy C. Shoemaker, David Grant, Marcia Imsande
Pages 357-378
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- Steven J. Knapp, Simon T. Berry, Loren H. Rieseberg
Pages 379-403
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- Anne Frary, Steven D. Tanksley
Pages 405-420
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- S. F. Kianian, S. L. Fox, S. Groh, N. Tinker, L. S. O’Donoughue, P. J. Rayapati et al.
Pages 443-462
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- Oscar Riera-Lizarazu, M. Isabel Vales, Ronald L. Phillips
Pages 463-497
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Back Matter
Pages 499-513
About this book
The double helix architecture of DNA was elucidated in 1953. Twenty years later, in 1973, the discovery of restriction enzymes helped to create recombinant DNA mol ecules in vitro. The implications of these powerful and novel methods of molecular biol ogy, and their potential in the genetic manipulation and improvement of microbes, plants and animals, became increasingly evident, and led to the birth of modern biotechnology. The first transgenic plants in which a bacterial gene had been stably integrated were produced in 1983, and by 1993 transgenic plants had been produced in all major crop species, including the cereals and the legumes. These remarkable achievements have resulted in the production of crops that are resistant to potent but environmentally safe herbicides, or to viral pathogens and insect pests. In other instances genes have been introduced that delay fruit ripening, or increase starch content, or cause male sterility. Most of these manipulations are based on the introduction of a single gene - generally of bacterial origin - that regulates an important monogenic trait, into the crop of choice. Many of the engineered crops are now under field trials and are expected to be commercially produced within the next few years.
Reviews
`Overall, the book is a very useful overview of DNA marker technology. It nicely complements existing manuals, such as DNA Marker: Protocols, Applications and Overviews. Many graduate students, researchers beginning in a new area or those wishing to learn about this fast developing field will also find it worthwhile. It could also be useful for plant breeders, and bioinformatics specialists serving the plant science community.'
Plant Science, 161 (2001)
Editors and Affiliations
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Department of Agronomy and Plant Genetics, University of Minnesota, St. Paul, USA
Ronald L. Phillips
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Laboratory of Plant Cell and Molecular Biology, University of Florida, Gainesville, USA
Indra K. Vasil