Principles of Plant Genetics and Breeding. George Acquaah

Principles of Plant Genetics and Breeding - George Acquaah


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there is a general perception that such creations derive from crossing different plants. This introductory chapter is devoted to presenting a brief overview of plant breeding, including its benefits to society and some historical perspectives. After completing this chapter, the student should have a general understanding of:

      1 The need and importance of plant breeding to society.

      2 The goals of plant breeding.

      3 The art and science of plant breeding.

      4 Trends in plant breeding as an industry.

      5 Selected milestones and accomplishments of plant breeders.

      6 The future of plant breeding in society.

      Plant breeders specialize in breeding different groups of plants. Some focus on field crops (e.g. soybean, cotton), horticultural food crops (e.g. vegetables), ornamentals (e.g. roses, pine trees), fruit trees (e.g. citrus, apple), forage crops (e.g. alfalfa, grasses), or turf species (e.g. Bluegrass, fescue). More importantly, breeders tend to specialize in or focus on specific species in these groups (e.g. corn breeder, potato breeder). This way, they develop the expertise that enables them to be most effective in improving the species of their choice. The principles and concepts discussed in this book are generally applicable to breeding all plant species.

      The plant breeder uses various technologies and methodologies to achieve targeted and directional changes in the nature of plants (nudge nature to the advantage of humans). As science and technology advance, new tools are developed while old ones are refined for use by breeders. Before initiating a breeding project, clear breeding objectives are defined based on factors such as producer needs, consumer preferences and needs, and environmental impact. Breeders aim to make the crop producer's job easier and more effective in various ways. They may modify plant structure so it would resist lodging and thereby facilitate mechanical harvesting. They may develop plants that resist pests so the farmer does not have to apply pesticides, or apply smaller amounts of these chemicals. Not applying pesticides in crop production means less environmental pollution from agricultural sources. Breeders may also develop high yielding varieties (or cultivars) so the farmer can produce more for the market to meet consumer demands while improving his or her income. The term cultivar is reserved for variants deliberately created by plant breeders and will be introduced more formally later in the book. It will be the term of choice in this book.

      When breeders think of consumers, they may, for example, develop foods with higher nutritional value and that are more flavorful. Higher nutritional value means reduced illnesses in society (e.g. nutritionally related ones such as blindness, rickettsia) caused by the consumption of nutrient‐deficient foods, as occurs in many developing regions where staple foods (e.g. rice, cassava) often lack certain essential amino acids or nutrients. Plant breeders may also target traits of industrial value. For example, fiber characteristics (e.g. strength) of fiber crops such as cotton can be improved, while oil crops can be improved to yield high amounts of specific fatty acids (e.g. high oleic content of sunflower seed). Latest advances in technology, specifically genetic engineering technologies, are being applied to enable plants to be used as bioreactors to produce certain pharmaceuticals (called biopharming or simply pharming).

      The technological capabilities and needs of societies of old restricted plant breeders then to achieving modest objectives (e.g. product appeal, adaptation to production environment). It should be pointed out that these “older” breeding objectives are still important today. However, with the availability of sophisticated tools, plant breeders are now able to accomplish these genetic alterations in novel ways that are sometimes the only option, or are more precise and more effective. Furthermore, as previously indicated, they are able to undertake more dramatic alterations that were impossible to attain in the past (e.g. transferring a desirable gene from a bacterium to a plant!). Some of the reasons why plant breeding is important to society are summarized next.

      The work of Gregor Mendel and further advances in science that followed his discoveries established that plant characteristics are controlled by hereditary factors or genes that consist of DNA (deoxyribose nucleic acid, the hereditary material). These genes are expressed in an environment to produce a trait. It follows then that in order to change a trait or its expression, one may change the nature or its genotype, and/or modify the nurture (environment in which it is expressed). Changing the environment essentially entails modifying the growing or production conditions. This may be achieved through an agronomic approach, for example the application of production inputs (e.g. fertilizers, irrigation). Whereas this approach is effective in enhancing certain traits, the fact remains that once these supplemental environmental factors are removed, the expression of the plant trait reverts to status quo. On the other hand, plant breeders seek to modify plants with respect to the expression of certain selected attributes by modifying the genotype (in a desired way by targeting specific genes). Such an approach produces an alteration that is permanent (i.e. transferable from one generation to the next).

      1.4.1 Addressing world food and feed quality needs


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