'Artificial selection' is the intentional breeding of certain traits, or combinations of traits, over others. It was originally defined by
Charles Darwin in contrast to the process of
natural selection, in which the differential reproduction of organisms with certain traits is attributed to improved survival and reproductive ability in the natural
habitat of the organism. Artificial selection that produces an undesirable outcome from a human perspective is sometimes called ''negative selection'' (but note that this term has a better-established meaning as a type of natural selection; see
negative selection).
Historical development
Charles Darwin originally coined the term as an illustration of his proposed wider process of natural selection. He noted that many domesticated animals and plants had special properties that were developed by intentionally encouraging the breeding potential of individuals who both possessed desirable characteristics, and discouraging the breeding of individuals who had less desirable characteristics.
Contrast to natural selection
The difference between natural and artificial selection centers on the difference in environment among organisms subject to the two processes. Essentially, in artificial selection, the
fitness, which is the amount of offspring an individual contributes to a population relative to other individuals in that same population of an organism, is defined in part by its display of the traits being selected for by human beings. Because humans either intentionally or unintentionally exert control over which organisms in a population reproduce or how many offspring they produce, the distribution of traits in the organisms' population will change.
It should be emphasized that there is no real difference in the genetic processes underlying artificial and natural selection, and that the concept of artificial selection was first introduced as an illustration of the wider process of natural selection. The selection process is termed "artificial" when human preferences or influences have a significant effect on the evolution of a particular population or species. Indeed, many evolutionary biologists view
domestication as a type of natural selection and adaptive change that occurs as organisms are brought under the control of human beings.
Laboratory usage
The deliberate exploitation of selective power has become common in experimental biology, particularly in
microbiology and
genetics. In a ubiquitous laboratory technique in
genetic engineering,
genes are introduced into
cells in
cell culture, usually
bacteria, on a small circular
DNA molecule called a
plasmid in a process called
transfection. The gene of interest is accompanied on the plasmid by a
reporter gene, or "selectable marker", which encodes a specific trait such as
antibiotic resistance or ability to grow in high salt concentrations. The cells can then be cultured in an environment that would kill normal cells, but is hospitable to those that have taken up and
expressed the genes on the plasmid. In this way expression of the reporter gene serves as a signal that the gene of interest is also being expressed in the cells.
Another technique used in
drug development uses an iterative selective process called
''in vitro'' selection to evolve
aptamers, or
nucleic acid fragments capable of binding specific
organic compounds with high binding affinity.
Studies in
evolutionary physiology,
behavioral genetics, and other areas of organismal biology have also made use of deliberate artificial selection, though longer
generation times and greater difficulty in breeding can make such projects challenging in vertebrates.
[1][2]
References
1. Swallow JG, Garland T. (2005). Selection experiments as a tool in evolutionary and comparative physiology: insights into complex traits—an introduction to the symposium. ''Integr Comp Biol'', 45:387–390.
2. Garland T. (2003). Selection experiments: an under-utilized tool in biomechanics and organismal biology. Ch.3, ''Vertebrate Biomechanics and Evolution'' ed. Bels VL, Gasc JP, Casinos A.
See also
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Eugenics
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Experimental evolution
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Inbreeding
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Quantitative genetics
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Selective breeding
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Gene pool
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Genetic Pollution
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Genetic Erosion
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