Overview
- Authors:
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Kenneth Mather
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University of Southampton, UK
University of Birmingham, UK
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John L. Jinks
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University of Birmingham, UK
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Table of contents (12 chapters)
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- Kenneth Mather, John L. Jinks
Pages 1-32
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- Kenneth Mather, John L. Jinks
Pages 33-48
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- Kenneth Mather, John L. Jinks
Pages 49-64
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- Kenneth Mather, John L. Jinks
Pages 65-82
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- Kenneth Mather, John L. Jinks
Pages 83-126
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- Kenneth Mather, John L. Jinks
Pages 127-171
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- Kenneth Mather, John L. Jinks
Pages 172-208
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- Kenneth Mather, John L. Jinks
Pages 209-248
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- Kenneth Mather, John L. Jinks
Pages 249-284
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- Kenneth Mather, John L. Jinks
Pages 285-307
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- Kenneth Mather, John L. Jinks
Pages 308-336
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- Kenneth Mather, John L. Jinks
Pages 337-366
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Back Matter
Pages 367-382
About this book
The properties of continuous variation are basic to the theory of evolution and to the practice of plant and animal improvement. Yet the genetical study of continuous variation has lagged far behind that of discontinuous variation. The reason for this situation is basically methodological. Mendel gave us not merely his principles of heredity, but also a method of experiment by which these principles could be tested over a wider range of living species, and extended into the elaborate genetical theory of today. The power of this tool is well attested by the speed with which genetics has grown. In less than fifty years, it has not only developed a theoretical structure which is unique in the biological sciences, but has established a union with nuclear cytology so close that the two have become virtually a single science offering us a new approach to problems so diverse as those of evolution, development, disease, cellular chemistry and human welfare. Much of this progress would have been impossible and all would have been slower without the Mendelian method of recognizing and using unit differences in the genetic materials.