fbpx
Wikipedia

Fixed allele

July 20, 2023

In population genetics, a fixed allele is an allele that is the only variant that exists for that gene in a population. A fixed allele is homozygous for all members of the population.[1] The process by which alleles become fixed is called fixation.

For this hypothetical species, the population in the topmost frame exhibits no fixed allele for "color". In contrast, the populations depicted in the latter frames exhibit fixed alleles for "color" black, red and purple respectively.

A population of a hypothetical species can be conceived to exemplify the concept of fixed alleles. If an allele is fixed in the population, then all organisms can have only that allele for the gene in question. Suppose that genotype corresponds directly to the phenotype of body color, then all organisms of the population would exhibit the same body color.

An allele in a population being fixed necessarily entails the phenotypic traits corresponding to that allele to be identical for all organisms in the population (if those genotypes correspond directly to a certain phenotype), as it follows logically from the definition of relevant concepts. However, identical phenotypic traits exhibited in a population does not necessarily entail the allele(s) corresponding to those traits to be fixed, as exemplified by the case of genetic dominance being apposite in a species' population. [2]

Low genetic diversity is accompanied by allele fixation, which can potentially lead to lower adaptibility to changing environmental conditions for a population as a whole. For example, often having certain alleles make an organism more susceptible to a disease than having other alleles; if an allele highly susceptible to a disease with a prevalent cause is fixed in a population, most organisms of the population might be affected. Hence, generally, populations exhibiting a significant range of fixed alleles are often at risk for extinction. [3][4]

Fixed alleles were first defined by Motoo Kimura in 1962.[5] Kimura discussed how fixed alleles could arise within populations and was the first to generalize the topic. He credits the works of Haldane in 1927[6] and Fisher in 1922[7] as being important in providing foundational information that allowed him to come to his conclusion.

The evolution of fixed alleles in populations

While there are many possibilities for how a fixed allele can develop, often multiple factors come into play simultaneously and guide the process, consequently determining the end result.

The two key driving forces behind fixation are natural selection and genetic drift. Natural selection was postulated by Charles Darwin and encompasses many processes that lead to the differential survival of organisms due to genetic or phenotypic differences. Genetic drift is the process by which allele frequencies fluctuate within populations. Natural selection and genetic drift propel evolution forward, and through evolution, alleles can become fixed.[8][9]

Processes of natural selection such as sexual, convergent, divergent, or stabilizing selection pave the way for allele fixation. One way some of these natural selection processes cause fixation is through one specific genotype or phenotype being favored, which leads to the convergence of the variability until one allele becomes fixed. Natural selection can work the other way, where two alleles become fixed through two specific genotypes or phenotypes being favored, leading to divergence within the population until the populations become so separate that they are now two species each with their own fixed allele.

Selective pressures can favor certain genotypes or phenotypes. A commonly known example of this is the process of antibiotic resistance within bacterial populations. As antibiotics are used to kill bacteria, a small number of them with favorable mutations can survive and repopulate in an environment that is now free of competition. The allele for antibiotic resistance then becomes a fixed allele within the surviving and future populations. This is an example of the bottleneck effect. A bottleneck occurs when a population is put under strong selective pressure, and only certain individuals survive. These surviving individuals have a decreased number of alleles present within their population than were present in the initial population, however, these remaining alleles are the only ones left in future populations assuming no mutation or migration. This bottleneck effect can also be seen in natural disasters, as shown in the rabbit example above.[10]

 
This image shows how though successive generations random allele fluctuations, or genetic drift, can lead to the fixation or loss of certain alleles within a population.

Similar to the bottleneck effect, the founder's effect can also cause allele fixation. The founder effect occurs when a small founding population is moved to a new area and propagates the future population. This can be seen in the Alces alces moose population in Newfoundland, Canada. Moose are not native to Newfoundland, and in 1878 and 1904 six total moose were introduced to the island. The six founding moose propagated the current population of an estimated 4000-6000 moose. This has had dramatic effects on the offspring of the founding moose and has led to a great decrease in genetic variability within the Newfoundland moose population as compared to the mainland population.[11][12]

Other random processes such as genetic drift can lead to fixation. Through these random processes, some random individuals or alleles are removed from the population. These random fluctuations within the allele frequencies can lead to the fixation or loss of certain alleles within a population. To the right is an image that shows through successive generations; the allele frequencies fluctuate randomly within a population. The smaller the population size, the faster fixation or loss of alleles will occur. However, all populations are driven to allele fixation and it is inevitable; it just takes varying amounts of time for this to occur due to population size.

Some other causes of allele fixation are inbreeding, as this decreases the genetic variability of the population and therefore decreases the effective population size.[11][13] This allows genetic drift to cause fixation faster than anticipated.

Isolation can also cause fixation, as it prevents the influx of new variable alleles into the population. This can often be seen on island populations, where the populations have a limited set of alleles. The only variability that can be added to these populations is through mutations.[11][12]

Examples

One example of a fixed allele is the DGAT-1 exon 8 in Anatolian buffalo. This is a non-conservative mutation in the DGAT-1 allele, which produces a protein with a lysine at position 232 instead of an alanine. This mutation produces a protein different from the wild type of protein. This mutation in cattle affects milk production. Investigation into three water buffalo populations revealed four different haplotypes each having a single nucleotide polymorphism (SNP), however, all of these SNPs were conservative mutations, causing no change in protein production. All populations of Anatolian buffalo studied had the non-conservative lysine mutation at 232, leading to the conclusion that this DGAT-1 allele mutation is fixed within the populations.[14]

The Parnassius apollo butterfly is classified as a threatened species, having many disjointed populations in the Western Palaearctic region. The population in the Mosel Valley of Germany has been genetically characterized and had been shown to have six long-term monomorphic microsatellites. Six microsatellites were examined by looking at the current population in 2008 as well as museum samples from 1895 to 1989. One of the microsatellite alleles examined has become fixed within the population before1895. For the current population, all six microsatellites as well as all sixteen alloenzymes analyzed were fixed.[15]

Fixed alleles can often be deleterious to populations, especially when there is small population size and low genetic variability. For example, the California Channel Island Fox (Urocyon littoralis) has the most monomorphic population ever reported for a sexually reproducing animal.[15] During the 1990s the Island Fox experienced disastrous population decline, leading to near extinction.[3] This population decline was caused in part by the canine distemper virus. The foxes were susceptible to this virus, and many were killed due to their genetic similarity. The introduction of a predator, the golden eagle, was also attributed to this population decline. With current conservation efforts, the population is in recovery.[4]

See also

References

  1. ^ "fixed allele definition". www.biochem.northwestern.edu.
  2. ^ "Genotype & Phenotype". biomed.brown.edu. Retrieved 2023-05-25.
  3. ^ a b Coonan, Timothy; Schwemma, Catherin; Roemerb, Gary; Garcelonc, David; Munsond, Linda (Mar 2005). "Decline of an Island Fox Subspecies to Near Extinction". The Southwestern Naturalist. 50: 32–41. doi:10.1894/0038-4909(2005)050<0032:DOAIFS>2.0.CO;2.
  4. ^ a b "Friends of the Island Fox: About Island Fox". www1.islandfox.org. Retrieved 2016-02-07.
  5. ^ Kimura, Motoo (1962-06-01). "On the Probability of Fixation of Mutant Genes in a Population". Genetics. 47 (6): 713–719. ISSN 0016-6731. PMC 1210364. PMID 14456043.
  6. ^ Haldane, J. B. S. (1927-07-01). "A Mathematical Theory of Natural and Artificial Selection, Part V: Selection and Mutation". Mathematical Proceedings of the Cambridge Philosophical Society. 23 (7): 838–844. Bibcode:1927PCPS...23..838H. doi:10.1017/S0305004100015644. ISSN 1469-8064.
  7. ^ Fisher, R. A. (1990-01-01). "On the dominance ratio". Bulletin of Mathematical Biology. 52 (1–2): 297–318. doi:10.1007/BF02459576. ISSN 0092-8240. PMID 2185862.
  8. ^ Hartwell, Leland (2011). Genetics: From Genes to Genomes. New York: McGraw-Hill. pp. 655–697. ISBN 978-0-07-352526-6.
  9. ^ Kimura, Motoo (1983). The Neutral Theory of Molecular Evolution - Cambridge Books Online - Cambridge University Press. doi:10.1017/cbo9780511623486. ISBN 9780511623486.
  10. ^ Molles, Manuel (2013). Ecology Concepts and Applications. New York: McGraw-Hill. ISBN 978-0-07353249-3.
  11. ^ a b c Broders, H. G.; Mahoney, S. P.; Montevecchi, W. A.; Davidson, W. S. (1999-08-01). "Population genetic structure and the effect of founder events on the genetic variability of moose, Alces alces, in Canada" (PDF). Molecular Ecology. 8 (8): 1309–1315. doi:10.1046/j.1365-294x.1999.00695.x. ISSN 0962-1083. PMID 10447871.
  12. ^ a b Frankham, R. (1997-03-01). "Heredity - Abstract of article: Do island populations have less genetic variation than mainland populations?". Heredity. 78 (3): 311–327. doi:10.1038/hdy.1997.46. ISSN 0018-067X. PMID 9119706.
  13. ^ Keller, Lukas F.; Waller, Donald M. (2002-05-01). "Inbreeding effects in wild populations". Trends in Ecology & Evolution. 17 (5): 230–241. doi:10.1016/S0169-5347(02)02489-8. ISSN 0169-5347.
  14. ^ Özdil, Fulya; Ilhan, Fatma (21 July 2012). "DGAT1-exon8 polymorphism in Anatolian buffalo" (PDF). Livestock Science. 149 (1–2): 83–87. doi:10.1016/j.livsci.2012.06.030. Retrieved 6 Feb 2016.
  15. ^ a b Habel, Jan Christian; Zachos, Frank Emmanuel; Finger, Aline; Meyer, Marc; Louy, Dirk; Assmann, Thorsten; Schmitt, Thomas (December 2009). "Unprecedented long-term genetic monomorphism in an endangered relict butterfly species". Conservation Genetics. 10 (6): 1659–1665. doi:10.1007/s10592-008-9744-5.

External links

  • Allele Fixation in Island Populations
  • Population Size and Genetic Drift
  • Population Genetics and Hardy Weinberg Equilibrium
  • Genetic Drift Simulation
  • Population Genetics Simulation

July 20, 2023
fixed, allele, population, genetics, fixed, allele, allele, that, only, variant, that, exists, that, gene, population, fixed, allele, homozygous, members, population, process, which, alleles, become, fixed, called, fixation, this, hypothetical, species, popula. In population genetics a fixed allele is an allele that is the only variant that exists for that gene in a population A fixed allele is homozygous for all members of the population 1 The process by which alleles become fixed is called fixation For this hypothetical species the population in the topmost frame exhibits no fixed allele for color In contrast the populations depicted in the latter frames exhibit fixed alleles for color black red and purple respectively A population of a hypothetical species can be conceived to exemplify the concept of fixed alleles If an allele is fixed in the population then all organisms can have only that allele for the gene in question Suppose that genotype corresponds directly to the phenotype of body color then all organisms of the population would exhibit the same body color An allele in a population being fixed necessarily entails the phenotypic traits corresponding to that allele to be identical for all organisms in the population if those genotypes correspond directly to a certain phenotype as it follows logically from the definition of relevant concepts However identical phenotypic traits exhibited in a population does not necessarily entail the allele s corresponding to those traits to be fixed as exemplified by the case of genetic dominance being apposite in a species population 2 Low genetic diversity is accompanied by allele fixation which can potentially lead to lower adaptibility to changing environmental conditions for a population as a whole For example often having certain alleles make an organism more susceptible to a disease than having other alleles if an allele highly susceptible to a disease with a prevalent cause is fixed in a population most organisms of the population might be affected Hence generally populations exhibiting a significant range of fixed alleles are often at risk for extinction 3 4 Fixed alleles were first defined by Motoo Kimura in 1962 5 Kimura discussed how fixed alleles could arise within populations and was the first to generalize the topic He credits the works of Haldane in 1927 6 and Fisher in 1922 7 as being important in providing foundational information that allowed him to come to his conclusion Contents 1 The evolution of fixed alleles in populations 2 Examples 3 See also 4 References 5 External linksThe evolution of fixed alleles in populations EditWhile there are many possibilities for how a fixed allele can develop often multiple factors come into play simultaneously and guide the process consequently determining the end result The two key driving forces behind fixation are natural selection and genetic drift Natural selection was postulated by Charles Darwin and encompasses many processes that lead to the differential survival of organisms due to genetic or phenotypic differences Genetic drift is the process by which allele frequencies fluctuate within populations Natural selection and genetic drift propel evolution forward and through evolution alleles can become fixed 8 9 Processes of natural selection such as sexual convergent divergent or stabilizing selection pave the way for allele fixation One way some of these natural selection processes cause fixation is through one specific genotype or phenotype being favored which leads to the convergence of the variability until one allele becomes fixed Natural selection can work the other way where two alleles become fixed through two specific genotypes or phenotypes being favored leading to divergence within the population until the populations become so separate that they are now two species each with their own fixed allele Selective pressures can favor certain genotypes or phenotypes A commonly known example of this is the process of antibiotic resistance within bacterial populations As antibiotics are used to kill bacteria a small number of them with favorable mutations can survive and repopulate in an environment that is now free of competition The allele for antibiotic resistance then becomes a fixed allele within the surviving and future populations This is an example of the bottleneck effect A bottleneck occurs when a population is put under strong selective pressure and only certain individuals survive These surviving individuals have a decreased number of alleles present within their population than were present in the initial population however these remaining alleles are the only ones left in future populations assuming no mutation or migration This bottleneck effect can also be seen in natural disasters as shown in the rabbit example above 10 This image shows how though successive generations random allele fluctuations or genetic drift can lead to the fixation or loss of certain alleles within a population Similar to the bottleneck effect the founder s effect can also cause allele fixation The founder effect occurs when a small founding population is moved to a new area and propagates the future population This can be seen in the Alces alces moose population in Newfoundland Canada Moose are not native to Newfoundland and in 1878 and 1904 six total moose were introduced to the island The six founding moose propagated the current population of an estimated 4000 6000 moose This has had dramatic effects on the offspring of the founding moose and has led to a great decrease in genetic variability within the Newfoundland moose population as compared to the mainland population 11 12 Other random processes such as genetic drift can lead to fixation Through these random processes some random individuals or alleles are removed from the population These random fluctuations within the allele frequencies can lead to the fixation or loss of certain alleles within a population To the right is an image that shows through successive generations the allele frequencies fluctuate randomly within a population The smaller the population size the faster fixation or loss of alleles will occur However all populations are driven to allele fixation and it is inevitable it just takes varying amounts of time for this to occur due to population size Some other causes of allele fixation are inbreeding as this decreases the genetic variability of the population and therefore decreases the effective population size 11 13 This allows genetic drift to cause fixation faster than anticipated Isolation can also cause fixation as it prevents the influx of new variable alleles into the population This can often be seen on island populations where the populations have a limited set of alleles The only variability that can be added to these populations is through mutations 11 12 Examples EditOne example of a fixed allele is the DGAT 1 exon 8 in Anatolian buffalo This is a non conservative mutation in the DGAT 1 allele which produces a protein with a lysine at position 232 instead of an alanine This mutation produces a protein different from the wild type of protein This mutation in cattle affects milk production Investigation into three water buffalo populations revealed four different haplotypes each having a single nucleotide polymorphism SNP however all of these SNPs were conservative mutations causing no change in protein production All populations of Anatolian buffalo studied had the non conservative lysine mutation at 232 leading to the conclusion that this DGAT 1 allele mutation is fixed within the populations 14 The Parnassius apollo butterfly is classified as a threatened species having many disjointed populations in the Western Palaearctic region The population in the Mosel Valley of Germany has been genetically characterized and had been shown to have six long term monomorphic microsatellites Six microsatellites were examined by looking at the current population in 2008 as well as museum samples from 1895 to 1989 One of the microsatellite alleles examined has become fixed within the population before1895 For the current population all six microsatellites as well as all sixteen alloenzymes analyzed were fixed 15 Fixed alleles can often be deleterious to populations especially when there is small population size and low genetic variability For example the California Channel Island Fox Urocyon littoralis has the most monomorphic population ever reported for a sexually reproducing animal 15 During the 1990s the Island Fox experienced disastrous population decline leading to near extinction 3 This population decline was caused in part by the canine distemper virus The foxes were susceptible to this virus and many were killed due to their genetic similarity The introduction of a predator the golden eagle was also attributed to this population decline With current conservation efforts the population is in recovery 4 See also EditAllele frequency Meiotic driveReferences Edit fixed allele definition www biochem northwestern edu Genotype amp Phenotype biomed brown edu Retrieved 2023 05 25 a b Coonan Timothy Schwemma Catherin Roemerb Gary Garcelonc David Munsond Linda Mar 2005 Decline of an Island Fox Subspecies to Near Extinction The Southwestern Naturalist 50 32 41 doi 10 1894 0038 4909 2005 050 lt 0032 DOAIFS gt 2 0 CO 2 a b Friends of the Island Fox About Island Fox www1 islandfox org Retrieved 2016 02 07 Kimura Motoo 1962 06 01 On the Probability of Fixation of Mutant Genes in a Population Genetics 47 6 713 719 ISSN 0016 6731 PMC 1210364 PMID 14456043 Haldane J B S 1927 07 01 A Mathematical Theory of Natural and Artificial Selection Part V Selection and Mutation Mathematical Proceedings of the Cambridge Philosophical Society 23 7 838 844 Bibcode 1927PCPS 23 838H doi 10 1017 S0305004100015644 ISSN 1469 8064 Fisher R A 1990 01 01 On the dominance ratio Bulletin of Mathematical Biology 52 1 2 297 318 doi 10 1007 BF02459576 ISSN 0092 8240 PMID 2185862 Hartwell Leland 2011 Genetics From Genes to Genomes New York McGraw Hill pp 655 697 ISBN 978 0 07 352526 6 Kimura Motoo 1983 The Neutral Theory of Molecular Evolution Cambridge Books Online Cambridge University Press doi 10 1017 cbo9780511623486 ISBN 9780511623486 Molles Manuel 2013 Ecology Concepts and Applications New York McGraw Hill ISBN 978 0 07353249 3 a b c Broders H G Mahoney S P Montevecchi W A Davidson W S 1999 08 01 Population genetic structure and the effect of founder events on the genetic variability of moose Alces alces in Canada PDF Molecular Ecology 8 8 1309 1315 doi 10 1046 j 1365 294x 1999 00695 x ISSN 0962 1083 PMID 10447871 a b Frankham R 1997 03 01 Heredity Abstract of article Do island populations have less genetic variation than mainland populations Heredity 78 3 311 327 doi 10 1038 hdy 1997 46 ISSN 0018 067X PMID 9119706 Keller Lukas F Waller Donald M 2002 05 01 Inbreeding effects in wild populations Trends in Ecology amp Evolution 17 5 230 241 doi 10 1016 S0169 5347 02 02489 8 ISSN 0169 5347 Ozdil Fulya Ilhan Fatma 21 July 2012 DGAT1 exon8 polymorphism in Anatolian buffalo PDF Livestock Science 149 1 2 83 87 doi 10 1016 j livsci 2012 06 030 Retrieved 6 Feb 2016 a b Habel Jan Christian Zachos Frank Emmanuel Finger Aline Meyer Marc Louy Dirk Assmann Thorsten Schmitt Thomas December 2009 Unprecedented long term genetic monomorphism in an endangered relict butterfly species Conservation Genetics 10 6 1659 1665 doi 10 1007 s10592 008 9744 5 External links EditAllele Fixation in Island Populations Population Size and Genetic Drift Population Genetics and Hardy Weinberg Equilibrium Genetic Drift Simulation Population Genetics Simulation Retrieved from https en wikipedia org w index php title Fixed allele amp oldid 1157078673, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.