BIO254:NaturalSelection: Difference between revisions
No edit summary |
No edit summary |
||
Line 32: | Line 32: | ||
Ecological selection (or environmental selection) refers to the ecological processes that operate on inherited traits without reference to mating or secondary sex characteristics. Examples of ecological selection are climate and geographical changes, competitions for limiting natural resources, interactions among individuals of the same species (including relatives (e.g. kin selection) and conspecifics(e.g. competition, infanticide)), etc. | Ecological selection (or environmental selection) refers to the ecological processes that operate on inherited traits without reference to mating or secondary sex characteristics. Examples of ecological selection are climate and geographical changes, competitions for limiting natural resources, interactions among individuals of the same species (including relatives (e.g. kin selection) and conspecifics(e.g. competition, infanticide)), etc. | ||
Sexual selection includes mechanisms such as mate choice and male-male competition. | Sexual selection includes mechanisms such as mate choice and male-male competition. Sexual selection can happen both intersexually and intrasexually. Within a species, when one sex (typically females) acts as a limiting resource for the other, compititions (typically between males)will occurs over the limiting sex, and this results in sexual selection. In the case that females choose males, usually the most vigorous and best adapted males will have the greatest number of offspring, and therefore the alleles coding these favorable traits are more likely to be pass down to the progeny. Intrasexual selection is often associated with sexual dimorphism, including differences in body size between males and females of a species. | ||
Natural selection happens at every life stage of an individual. Typical examples are shown in Figure 1. Selection at each of these stages can affect individuals' survivability and reproductive capcity. | Natural selection happens at every life stage of an individual. Typical examples are shown in Figure 1. Selection at each of these stages can affect individuals' survivability and reproductive capcity. |
Revision as of 22:53, 13 November 2006
Definition
Natural Selection is the process through which individuals with beneficial traits are more likely to survive and reproduce, and have better chances to pass on the traits to progeny, if the traits have heritable components. In the next generation, those traits tend to be more common. Through generations of accumulation, the traits will spread in the population, and can result in speciation and adaptation. On the other hand, individuals with injurious variations will have less chances to survive or reproduce, and their traits should be eliminated from the population.
The concept of “Natural Selection” was first introduced by Charles Darwin in his 1859 book “The Origin of Species by Means of Natural Selection”, by saying “…individuals having any advantage, however slight, over others, would have the best chance of surviving and of procreating their kind. On the other hand, we may feel sure that any variation in the least degree injurious would be rigidly destroyed. This preservation of favourable variations and the rejection of injurious variations, I call Natural Selection. " Natural Selection provides one of the most important mechanisms on evolution.
Genetic Basis of Natural Selection
After genetics and population biology were incorporated into the studies of evolution, people get a better understanding of natural selection. The existence of genes was first suggested by Gregor Mendel, in the 1860s. In 1910s, T. H. Morgan introduced the chromosome theory of inheritance, R. A. Fisher showed how continuous variation could be the result of the action of many discrete loci. Morgan's student Theodosius Dobzhansky was the first to apply Morgan's chromosome theory and the mathematics of population genetics to natural populations of organism. Their works, as well as contributions from many other scientists shed light on the genetic basis of natural selection.
Traits of an organism are coded by their genes. But for each gene, there might be some variations, or so-called different alleles. The genetic variation arises from random mutation and recombination, and provides the sources for natural selection. Populations evolve by changes in the relative allele frequency brought about by random genetic drift, gene flow, and especially natural selection. Different alleles may give rise to different traits, or phenotypes. Individuals with the phenotypes favorable for surviving or reproduce have more chances to pass the alleles to the offspring, so that the allele frequency will increase in the population. The favorable genetic variants may have individually slight phenotypic effects and phenotypic changes are gradual. Given enough time, the gradual evolution could give rise to changes of great magnitude, such as reproductive isolation, and result in speciation or designation of higher taxonomic levels.
Natural Selection vs Artificial Selection
In the book "The Origin of Species", Darwin coined the term natural selection in analog to artificial selection, the process by which a farmer selects his breeding stock. But in fact, natural selection and artificial seletion are quite different processes. It would be beneficial here to make some comparisons between them.
Artificial selection often encourages the breeding of individuals possessing "desirable" characteristics over others, from a human perspective, either intentionally or unintentionally. The choice to encourage or decourage certain characteristics are usually clearly directed. The species formed under artificial selection do not necessarily have the fitness under natural conditions. Besides, people can only choose to change the frequency of alleles that have observable phenotypes.
On the other hand, as Francois Jacob pointed,“… natural selection does not work as an engineer works. It works like a tinkerer – a tinkerer who does not know exactly what he is going to produce but uses whatever he finds around him whether it be pieces of string, fragments of wood, or old cardboard… Evolution does not produce novelties from scratch.”.
It should be noticed that the underlying genetic basis for both artificial selection and natural selection are the same, and that the concept of artificial selection was first introduced as an illustration of the wider process of natural selection.
Selection Condition
Concerning the selection forces, natural selection can generally be divided into two classes, ecological selection and sexual seletion.
Ecological selection (or environmental selection) refers to the ecological processes that operate on inherited traits without reference to mating or secondary sex characteristics. Examples of ecological selection are climate and geographical changes, competitions for limiting natural resources, interactions among individuals of the same species (including relatives (e.g. kin selection) and conspecifics(e.g. competition, infanticide)), etc.
Sexual selection includes mechanisms such as mate choice and male-male competition. Sexual selection can happen both intersexually and intrasexually. Within a species, when one sex (typically females) acts as a limiting resource for the other, compititions (typically between males)will occurs over the limiting sex, and this results in sexual selection. In the case that females choose males, usually the most vigorous and best adapted males will have the greatest number of offspring, and therefore the alleles coding these favorable traits are more likely to be pass down to the progeny. Intrasexual selection is often associated with sexual dimorphism, including differences in body size between males and females of a species.
Natural selection happens at every life stage of an individual. Typical examples are shown in Figure 1. Selection at each of these stages can affect individuals' survivability and reproductive capcity.
Fig 1. Natural selection occurs at different life stages of an individual.
Research History of Natural Selection
Pre-Darwinian Theories
Lamarckian idea of inheritance of acquired characteristics
Darwin
Neo-Darwinism
References
Darwin C. On the Origin of Species by Means of Natural Selection, or the Preservation of Favoured Races in the Struggle for Life John Murray, London; modern reprint Charles Darwin, Julian Huxley (2003). Chapter 4 - Natural Selection.
Futuyma, D.J. in Evolutionary Biology, Sinauer Associates, 1986; p.12
Tom Clandinin. Lecture Note. Chapter 13, Evolution of Sensory Systems.
Wikipedia, http://en.wikipedia.org/wiki/Natural_selection
Christiansen FB (1984) The definition and measurement of fitness. In: Evolutionary ecology (ed. Shorrocks B) pp65-79.
Recent updates to the site:
- N
- This edit created a new page (also see list of new pages)
- m
- This is a minor edit
- b
- This edit was performed by a bot
- (±123)
- The page size changed by this number of bytes
10 May 2024
15:04 | Karas Lab:Contact diffhist +76 Aclesage talk contribs |
15:02 | Karas Lab diffhist +505 Aclesage talk contribs |
|
14:55 | Beauchamp:iELVIS 2 changes history 0 [Zhou.oliverfr (2×)] | |||
|
14:55 (cur | prev) −3 Zhou.oliverfr talk contribs Tag: Manual revert | ||||
|
14:55 (cur | prev) +3 Zhou.oliverfr talk contribs |
|
14:39 | Altman:WUbites 2 changes history +258 [David Altman (2×)] | |||
|
14:39 (cur | prev) 0 David Altman talk contribs | ||||
|
14:36 (cur | prev) +258 David Altman talk contribs (→WUbites) |
14:36 | Upload log David Altman talk contribs uploaded File:Robbins WUbites Spring 2024.pdf |
13:19 | UA Biophysics: Spectrofluorometer Instructions ESP diffhist −433 Elizabeth Suesca talk contribs |
10:23 | Ernesto-Perez-Rueda:Publications diffhist +262 Ernesto Perez-Rueda talk contribs |
9 May 2024
|
18:42 | Renhao Li Lab:Publications 7 changes history +261 [Renhao Li (7×)] | |||
|
18:42 (cur | prev) +3 Renhao Li talk contribs (→2024) | ||||
|
18:42 (cur | prev) +14 Renhao Li talk contribs (→2024) | ||||
|
18:41 (cur | prev) +72 Renhao Li talk contribs (→2024) | ||||
|
18:30 (cur | prev) −2 Renhao Li talk contribs (→2024) | ||||
|
18:22 (cur | prev) 0 Renhao Li talk contribs (→2024) | ||||
|
18:21 (cur | prev) +173 Renhao Li talk contribs (→2024) | ||||
|
18:18 (cur | prev) +1 Renhao Li talk contribs (→2024) |
18:26 | Renhao Li Lab:Lab Members diffhist −835 Renhao Li talk contribs (→Current Members) |
|
18:23 | (Upload log) [Renhao Li; David Altman (9×)] | |||
|
18:23 Renhao Li talk contribs uploaded File:097vwfNbs abstract.png | ||||
|
15:24 David Altman talk contribs uploaded File:Martin WUbites Spring 2024.pdf | ||||
|
14:48 David Altman talk contribs uploaded File:CampiTalk.jpg | ||||
|
14:39 David Altman talk contribs uploaded File:JuniorPresentations.jpg | ||||
|
14:39 David Altman talk contribs uploaded File:SeniorPresentations.jpg | ||||
|
14:28 David Altman talk contribs uploaded File:SkypeaScientist January2024.jpeg | ||||
|
14:18 David Altman talk contribs uploaded File:Isaacson WUbitres Spring 2024.pdf | ||||
|
14:14 David Altman talk contribs uploaded File:Corado WUbites Spring 2024.pdf | ||||
|
14:12 David Altman talk contribs uploaded File:DeBois WUbites Spring 2024.pdf | ||||
|
14:05 David Altman talk contribs uploaded File:Tinat WUbites Spring 2024.pdf |
|
14:51 | Altman:Pictures 8 changes history +808 [David Altman (8×)] | |||
|
14:51 (cur | prev) +1 David Altman talk contribs | ||||
|
14:50 (cur | prev) +6 David Altman talk contribs | ||||
|
14:50 (cur | prev) −6 David Altman talk contribs | ||||
|
14:47 (cur | prev) +197 David Altman talk contribs | ||||
|
14:42 (cur | prev) +10 David Altman talk contribs | ||||
|
14:41 (cur | prev) −8 David Altman talk contribs | ||||
|
14:39 (cur | prev) +372 David Altman talk contribs | ||||
|
14:33 (cur | prev) +236 David Altman talk contribs |