| Title |
The fundamental theorem of natural selection with mutations
|
|---|---|
| Published in |
Journal of Mathematical Biology, November 2017
|
| DOI | 10.1007/s00285-017-1190-x |
| Pubmed ID | |
| Authors |
William F. Basener, John C. Sanford |
| Abstract |
The mutation-selection process is the most fundamental mechanism of evolution. In 1935, R. A. Fisher proved his fundamental theorem of natural selection, providing a model in which the rate of change of mean fitness is equal to the genetic variance of a species. Fisher did not include mutations in his model, but believed that mutations would provide a continual supply of variance resulting in perpetual increase in mean fitness, thus providing a foundation for neo-Darwinian theory. In this paper we re-examine Fisher's Theorem, showing that because it disregards mutations, and because it is invalid beyond one instant in time, it has limited biological relevance. We build a differential equations model from Fisher's first principles with mutations added, and prove a revised theorem showing the rate of change in mean fitness is equal to genetic variance plus a mutational effects term. We refer to our revised theorem as the fundamental theorem of natural selection with mutations. Our expanded theorem, and our associated analyses (analytic computation, numerical simulation, and visualization), provide a clearer understanding of the mutation-selection process, and allow application of biologically realistic parameters such as mutational effects. The expanded theorem has biological implications significantly different from what Fisher had envisioned. |
X Demographics
The data shown below were collected from the profiles of 31 X users who shared this research output. Click here to find out more about how the information was compiled.
Geographical breakdown
| Country | Count | As % |
|---|---|---|
| Netherlands | 4 | 13% |
| United States | 3 | 10% |
| United Kingdom | 2 | 6% |
| Uganda | 1 | 3% |
| Brazil | 1 | 3% |
| Japan | 1 | 3% |
| Canada | 1 | 3% |
| Norway | 1 | 3% |
| Unknown | 17 | 55% |
Demographic breakdown
| Type | Count | As % |
|---|---|---|
| Members of the public | 23 | 74% |
| Scientists | 7 | 23% |
| Science communicators (journalists, bloggers, editors) | 1 | 3% |
Mendeley readers
The data shown below were compiled from readership statistics for 80 Mendeley readers of this research output. Click here to see the associated Mendeley record.
Geographical breakdown
| Country | Count | As % |
|---|---|---|
| Unknown | 80 | 100% |
Demographic breakdown
| Readers by professional status | Count | As % |
|---|---|---|
| Researcher | 12 | 15% |
| Student > Ph. D. Student | 11 | 14% |
| Student > Bachelor | 8 | 10% |
| Professor | 6 | 8% |
| Other | 6 | 8% |
| Other | 14 | 18% |
| Unknown | 23 | 29% |
| Readers by discipline | Count | As % |
|---|---|---|
| Agricultural and Biological Sciences | 16 | 20% |
| Biochemistry, Genetics and Molecular Biology | 12 | 15% |
| Mathematics | 6 | 8% |
| Engineering | 4 | 5% |
| Environmental Science | 3 | 4% |
| Other | 11 | 14% |
| Unknown | 28 | 35% |
Attention Score in Context
This research output has an Altmetric Attention Score of 47. This is our high-level measure of the quality and quantity of online attention that it has received. This Attention Score, as well as the ranking and number of research outputs shown below, was calculated when the research output was last mentioned on 25 April 2024.
All research outputs
#915,744
of 25,782,917 outputs
Outputs from Journal of Mathematical Biology
#10
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Outputs of similar age
#18,964
of 344,061 outputs
Outputs of similar age from Journal of Mathematical Biology
#1
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