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Neutral theory of molecular evolution

January 01, 1970

The neutral theory of molecular evolution holds that most evolutionary changes occur at the molecular level, and most of the variation within and between species are due to random genetic drift of mutant alleles that are selectively neutral. The theory applies only for evolution at the molecular level, and is compatible with phenotypic evolution being shaped by natural selection as postulated by Charles Darwin.

The neutral theory allows for the possibility that most mutations are deleterious, but holds that because these are rapidly removed by natural selection, they do not make significant contributions to variation within and between species at the molecular level. A neutral mutation is one that does not affect an organism's ability to survive and reproduce.

The neutral theory assumes that most mutations that are not deleterious are neutral rather than beneficial. Because only a fraction of gametes are sampled in each generation of a species, the neutral theory suggests that a mutant allele can arise within a population and reach fixation by chance, rather than by selective advantage.[1]

The theory was introduced by the Japanese biologist Motoo Kimura in 1968, and independently by two American biologists Jack Lester King and Thomas Hughes Jukes in 1969, and described in detail by Kimura in his 1983 monograph The Neutral Theory of Molecular Evolution. The proposal of the neutral theory was followed by an extensive "neutralist–selectionist" controversy over the interpretation of patterns of molecular divergence and gene polymorphism, peaking in the 1970s and 1980s.

Neutral theory is frequently used as the null hypothesis, as opposed to adaptive explanations, for describing the emergence of morphological or genetic features in organisms and populations. This has been suggested in a number of areas, including in explaining genetic variation between populations of one nominal species,[2] the emergence of complex subcellular machinery,[3] and the convergent emergence of several typical microbial morphologies.[4]

Origins edit

While some scientists, such as Freese (1962)[5] and Freese and Yoshida (1965),[6] had suggested that neutral mutations were probably widespread, the original mathematical derivation of the theory had been published by R.A. Fisher in 1930.[7] Fisher, however, gave a reasoned argument for believing that, in practice, neutral gene substitutions would be very rare.[8] A coherent theory of neutral evolution was first proposed by Motoo Kimura in 1968[9] and by King and Jukes independently in 1969.[10] Kimura initially focused on differences among species; King and Jukes focused on differences within species.

Many molecular biologists and population geneticists also contributed to the development of the neutral theory.[1][11][12] The principles of population genetics, established by J.B.S. Haldane, R.A. Fisher, and Sewall Wright, created a mathematical approach to analyzing gene frequencies that contributed to the development of Kimura's theory.

Haldane's dilemma regarding the cost of selection was used as motivation by Kimura. Haldane estimated that it takes about 300 generations for a beneficial mutation to become fixed in a mammalian lineage, meaning that the number of substitutions (1.5 per year) in the evolution between humans and chimpanzees was too high to be explained by beneficial mutations.

Functional constraint edit

The neutral theory holds that as functional constraint diminishes, the probability that a mutation is neutral rises, and so should the rate of sequence divergence.

When comparing various proteins, extremely high evolutionary rates were observed in proteins such as fibrinopeptides and the C chain of the proinsulin molecule, which both have little to no functionality compared to their active molecules. Kimura and Ohta also estimated that the alpha and beta chains on the surface of a hemoglobin protein evolve at a rate almost ten times faster than the inside pockets, which would imply that the overall molecular structure of hemoglobin is less significant than the inside where the iron-containing heme groups reside.[13]

There is evidence that rates of nucleotide substitution are particularly high in the third position of a codon, where there is little functional constraint.[14] This view is based in part on the degenerate genetic code, in which sequences of three nucleotides (codons) may differ and yet encode the same amino acid (GCC and GCA both encode alanine, for example). Consequently, many potential single-nucleotide changes are in effect "silent" or "unexpressed" (see synonymous or silent substitution). Such changes are presumed to have little or no biological effect.[15]

Quantitative theory edit

Kimura also developed the infinite sites model (ISM) to provide insight into evolutionary rates of mutant alleles. If   were to represent the rate of mutation of gametes per generation of   individuals, each with two sets of chromosomes, the total number of new mutants in each generation is  . Now let   represent the evolution rate in terms of a mutant allele   becoming fixed in a population.[16]

 

According to ISM, selectively neutral mutations appear at rate   in each of the   copies of a gene, and fix with probability  . Because any of the   genes have the ability to become fixed in a population,   is equal to  , resulting in the rate of evolutionary rate equation:

 

This means that if all mutations were neutral, the rate at which fixed differences accumulate between divergent populations is predicted to be equal to the per-individual mutation rate, independent of population size. When the proportion of mutations that are neutral is constant, so is the divergence rate between populations. This provides a rationale for the molecular clock, which predated neutral theory.[17] The ISM also demonstrates a constancy that is observed in molecular lineages.

This stochastic process is assumed to obey equations describing random genetic drift by means of accidents of sampling, rather than for example genetic hitchhiking of a neutral allele due to genetic linkage with non-neutral alleles. After appearing by mutation, a neutral allele may become more common within the population via genetic drift. Usually, it will be lost, or in rare cases it may become fixed, meaning that the new allele becomes standard in the population.

According to the neutral theory of molecular evolution, the amount of genetic variation within a species should be proportional to the effective population size.

The "neutralist–selectionist" debate edit

See also: History of evolutionary thought and History of molecular evolution

A heated debate arose when Kimura's theory was published, largely revolving around the relative percentages of polymorphic and fixed alleles that are "neutral" versus "non-neutral".

A genetic polymorphism means that different forms of particular genes, and hence of the proteins that they produce, are co-existing within a species. Selectionists claimed that such polymorphisms are maintained by balancing selection, while neutralists view the variation of a protein as a transient phase of molecular evolution.[1] Studies by Richard K. Koehn and W. F. Eanes demonstrated a correlation between polymorphism and molecular weight of their molecular subunits.[18] This is consistent with the neutral theory assumption that larger subunits should have higher rates of neutral mutation. Selectionists, on the other hand, contribute environmental conditions to be the major determinants of polymorphisms rather than structural and functional factors.[16]

According to the neutral theory of molecular evolution, the amount of genetic variation within a species should be proportional to the effective population size. Levels of genetic diversity vary much less than census population sizes, giving rise to the "paradox of variation" .[19] While high levels of genetic diversity were one of the original arguments in favor of neutral theory, the paradox of variation has been one of the strongest arguments against neutral theory.

There are a large number of statistical methods for testing whether neutral theory is a good description of evolution (e.g., McDonald-Kreitman test[20]), and many authors claimed detection of selection.[21][22][23][24][25][26] Some researchers have nevertheless argued that the neutral theory still stands, while expanding the definition of neutral theory to include background selection at linked sites.[27]

Nearly neutral theory edit

Tomoko Ohta also emphasized the importance of nearly neutral mutations, in particularly slightly deleterious mutations.[28] The Nearly neutral theory stems from the prediction of neutral theory that the balance between selection and genetic drift depends on effective population size.[29] Nearly neutral mutations are those that carry selection coefficients less than the inverse of twice the effective population size.[30] The population dynamics of nearly neutral mutations are only slightly different from those of neutral mutations unless the absolute magnitude of the selection coefficient is greater than 1/N, where N is the effective population size in respect of selection.[1][11][12] The effective population size affects whether slightly deleterious mutations can be treated as neutral or as deleterious.[31] In large populations, selection can decrease the frequency of slightly deleterious mutations, therefore acting as if they are deleterious. However, in small populations, genetic drift can more easily overcome selection, causing slightly deleterious mutations to act as if they are neutral and drift to fixation or loss.[31]

Constructive neutral evolution edit

Further information: Constructive neutral evolution

The groundworks for the theory of constructive neutral evolution (CNE) was laid by two papers in the 1990s.[32][33][34] Constructive neutral evolution is a theory which suggests that complex structures and processes can emerge through neutral transitions. Although a separate theory altogether, the emphasis on neutrality as a process whereby neutral alleles are randomly fixed by genetic drift finds some inspiration from the earlier attempt by the neutral theory to invoke its importance in evolution.[34] Conceptually, there are two components A and B (which may represent two proteins) which interact with each other. A, which performs a function for the system, does not depend on its interaction with B for its functionality, and the interaction itself may have randomly arisen in an individual with the ability to disappear without an effect on the fitness of A. This present yet currently unnecessary interaction is therefore called an "excess capacity" of the system. However, a mutation may occur which compromises the ability of A to perform its function independently. However, the A:B interaction that has already emerged sustains the capacity of A to perform its initial function. Therefore, the emergence of the A:B interaction "presuppresses" the deleterious nature of the mutation, making it a neutral change in the genome that is capable of spreading through the population via random genetic drift. Hence, A has gained a dependency on its interaction with B.[35] In this case, the loss of B or the A:B interaction would have a negative effect on fitness and so purifying selection would eliminate individuals where this occurs. While each of these steps are individually reversible (for example, A may regain the capacity to function independently or the A:B interaction may be lost), a random sequence of mutations tends to further reduce the capacity of A to function independently and a random walk through the dependency space may very well result in a configuration in which a return to functional independence of A is far too unlikely to occur, which makes CNE a one-directional or "ratchet-like" process.[36] CNE, which does not invoke adaptationist mechanisms for the origins of more complex systems (which involve more parts and interactions contributing to the whole), has seen application in the understanding of the evolutionary origins of the spliceosomal eukaryotic complex, RNA editing, additional ribosomal proteins beyond the core, the emergence of long-noncoding RNA from junk DNA, and so forth.[37][38][39][40] In some cases, ancestral sequence reconstruction techniques have afforded the ability for experimental demonstration of some proposed examples of CNE, as in heterooligomeric ring protein complexes in some fungal lineages.[41]

CNE has also been put forwards as the null hypothesis for explaining complex structures, and thus adaptationist explanations for the emergence of complexity must be rigorously tested on a case-by-case basis against this null hypothesis prior to acceptance. Grounds for invoking CNE as a null include that it does not presume that changes offered an adaptive benefit to the host or that they were directionally selected for, while maintaining the importance of more rigorous demonstrations of adaptation when invoked so as to avoid the excessive flaws of adaptationism criticized by Gould and Lewontin.[42][3][43]

Empirical evidence for the neutral theory edit

Predictions derived from the neutral theory are generally supported in studies of molecular evolution.[44] One of corollaries of the neutral theory is that the efficiency of positive selection is higher in populations or species with higher effective population sizes.[45] This relationship between the effective population size and selection efficiency was evidenced by genomic studies of species including chimpanzee and human[45] and domesticated species.[46] In small populations (e.g., a population bottleneck during a speciation event), slightly deleterious mutations should accumulate. Data from various species supports this prediction in that the ratio of nonsynonymous to synonymous nucleotide substitutions between species generally exceeds that within species.[31] In addition, nucleotide and amino acid substitutions generally accumulate over time in a linear fashion, which is consistent with neutral theory.[44] Arguments against the neutral theory cite evidence of widespread positive selection and selective sweeps in genomic data.[47] Empirical support for the neutral theory may vary depending on the type of genomic data studied and the statistical tools used to detect positive selection.[44] For example, Bayesian methods for the detection of selected codon sites and McDonald-Kreitman tests have been criticized for their rate of erroneous identification of positive selection.[31][44]

See also edit

References edit

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External links edit

January 01, 1970
neutral, theory, molecular, evolution, neutral, theory, molecular, evolution, holds, that, most, evolutionary, changes, occur, molecular, level, most, variation, within, between, species, random, genetic, drift, mutant, alleles, that, selectively, neutral, the. The neutral theory of molecular evolution holds that most evolutionary changes occur at the molecular level and most of the variation within and between species are due to random genetic drift of mutant alleles that are selectively neutral The theory applies only for evolution at the molecular level and is compatible with phenotypic evolution being shaped by natural selection as postulated by Charles Darwin The neutral theory allows for the possibility that most mutations are deleterious but holds that because these are rapidly removed by natural selection they do not make significant contributions to variation within and between species at the molecular level A neutral mutation is one that does not affect an organism s ability to survive and reproduce The neutral theory assumes that most mutations that are not deleterious are neutral rather than beneficial Because only a fraction of gametes are sampled in each generation of a species the neutral theory suggests that a mutant allele can arise within a population and reach fixation by chance rather than by selective advantage 1 The theory was introduced by the Japanese biologist Motoo Kimura in 1968 and independently by two American biologists Jack Lester King and Thomas Hughes Jukes in 1969 and described in detail by Kimura in his 1983 monograph The Neutral Theory of Molecular Evolution The proposal of the neutral theory was followed by an extensive neutralist selectionist controversy over the interpretation of patterns of molecular divergence and gene polymorphism peaking in the 1970s and 1980s Neutral theory is frequently used as the null hypothesis as opposed to adaptive explanations for describing the emergence of morphological or genetic features in organisms and populations This has been suggested in a number of areas including in explaining genetic variation between populations of one nominal species 2 the emergence of complex subcellular machinery 3 and the convergent emergence of several typical microbial morphologies 4 Contents 1 Origins 2 Functional constraint 3 Quantitative theory 4 The neutralist selectionist debate 5 Nearly neutral theory 6 Constructive neutral evolution 7 Empirical evidence for the neutral theory 8 See also 9 References 10 External linksOrigins editWhile some scientists such as Freese 1962 5 and Freese and Yoshida 1965 6 had suggested that neutral mutations were probably widespread the original mathematical derivation of the theory had been published by R A Fisher in 1930 7 Fisher however gave a reasoned argument for believing that in practice neutral gene substitutions would be very rare 8 A coherent theory of neutral evolution was first proposed by Motoo Kimura in 1968 9 and by King and Jukes independently in 1969 10 Kimura initially focused on differences among species King and Jukes focused on differences within species Many molecular biologists and population geneticists also contributed to the development of the neutral theory 1 11 12 The principles of population genetics established by J B S Haldane R A Fisher and Sewall Wright created a mathematical approach to analyzing gene frequencies that contributed to the development of Kimura s theory Haldane s dilemma regarding the cost of selection was used as motivation by Kimura Haldane estimated that it takes about 300 generations for a beneficial mutation to become fixed in a mammalian lineage meaning that the number of substitutions 1 5 per year in the evolution between humans and chimpanzees was too high to be explained by beneficial mutations Functional constraint editThe neutral theory holds that as functional constraint diminishes the probability that a mutation is neutral rises and so should the rate of sequence divergence When comparing various proteins extremely high evolutionary rates were observed in proteins such as fibrinopeptides and the C chain of the proinsulin molecule which both have little to no functionality compared to their active molecules Kimura and Ohta also estimated that the alpha and beta chains on the surface of a hemoglobin protein evolve at a rate almost ten times faster than the inside pockets which would imply that the overall molecular structure of hemoglobin is less significant than the inside where the iron containing heme groups reside 13 There is evidence that rates of nucleotide substitution are particularly high in the third position of a codon where there is little functional constraint 14 This view is based in part on the degenerate genetic code in which sequences of three nucleotides codons may differ and yet encode the same amino acid GCC and GCA both encode alanine for example Consequently many potential single nucleotide changes are in effect silent or unexpressed see synonymous or silent substitution Such changes are presumed to have little or no biological effect 15 Quantitative theory editKimura also developed the infinite sites model ISM to provide insight into evolutionary rates of mutant alleles If v displaystyle v nbsp were to represent the rate of mutation of gametes per generation of N displaystyle N nbsp individuals each with two sets of chromosomes the total number of new mutants in each generation is 2 N v displaystyle 2Nv nbsp Now let k displaystyle k nbsp represent the evolution rate in terms of a mutant allele m displaystyle mu nbsp becoming fixed in a population 16 k 2 N v m displaystyle k 2Nv mu nbsp According to ISM selectively neutral mutations appear at rate m displaystyle mu nbsp in each of the 2 N displaystyle 2N nbsp copies of a gene and fix with probability 1 2 N displaystyle 1 2N nbsp Because any of the 2 N displaystyle 2N nbsp genes have the ability to become fixed in a population 1 2 N displaystyle 1 2N nbsp is equal to m displaystyle mu nbsp resulting in the rate of evolutionary rate equation k v displaystyle k v nbsp This means that if all mutations were neutral the rate at which fixed differences accumulate between divergent populations is predicted to be equal to the per individual mutation rate independent of population size When the proportion of mutations that are neutral is constant so is the divergence rate between populations This provides a rationale for the molecular clock which predated neutral theory 17 The ISM also demonstrates a constancy that is observed in molecular lineages This stochastic process is assumed to obey equations describing random genetic drift by means of accidents of sampling rather than for example genetic hitchhiking of a neutral allele due to genetic linkage with non neutral alleles After appearing by mutation a neutral allele may become more common within the population via genetic drift Usually it will be lost or in rare cases it may become fixed meaning that the new allele becomes standard in the population According to the neutral theory of molecular evolution the amount of genetic variation within a species should be proportional to the effective population size The neutralist selectionist debate editSee also History of evolutionary thought and History of molecular evolution A heated debate arose when Kimura s theory was published largely revolving around the relative percentages of polymorphic and fixed alleles that are neutral versus non neutral A genetic polymorphism means that different forms of particular genes and hence of the proteins that they produce are co existing within a species Selectionists claimed that such polymorphisms are maintained by balancing selection while neutralists view the variation of a protein as a transient phase of molecular evolution 1 Studies by Richard K Koehn and W F Eanes demonstrated a correlation between polymorphism and molecular weight of their molecular subunits 18 This is consistent with the neutral theory assumption that larger subunits should have higher rates of neutral mutation Selectionists on the other hand contribute environmental conditions to be the major determinants of polymorphisms rather than structural and functional factors 16 According to the neutral theory of molecular evolution the amount of genetic variation within a species should be proportional to the effective population size Levels of genetic diversity vary much less than census population sizes giving rise to the paradox of variation 19 While high levels of genetic diversity were one of the original arguments in favor of neutral theory the paradox of variation has been one of the strongest arguments against neutral theory There are a large number of statistical methods for testing whether neutral theory is a good description of evolution e g McDonald Kreitman test 20 and many authors claimed detection of selection 21 22 23 24 25 26 Some researchers have nevertheless argued that the neutral theory still stands while expanding the definition of neutral theory to include background selection at linked sites 27 Nearly neutral theory editTomoko Ohta also emphasized the importance of nearly neutral mutations in particularly slightly deleterious mutations 28 The Nearly neutral theory stems from the prediction of neutral theory that the balance between selection and genetic drift depends on effective population size 29 Nearly neutral mutations are those that carry selection coefficients less than the inverse of twice the effective population size 30 The population dynamics of nearly neutral mutations are only slightly different from those of neutral mutations unless the absolute magnitude of the selection coefficient is greater than 1 N where N is the effective population size in respect of selection 1 11 12 The effective population size affects whether slightly deleterious mutations can be treated as neutral or as deleterious 31 In large populations selection can decrease the frequency of slightly deleterious mutations therefore acting as if they are deleterious However in small populations genetic drift can more easily overcome selection causing slightly deleterious mutations to act as if they are neutral and drift to fixation or loss 31 Constructive neutral evolution editFurther information Constructive neutral evolution The groundworks for the theory of constructive neutral evolution CNE was laid by two papers in the 1990s 32 33 34 Constructive neutral evolution is a theory which suggests that complex structures and processes can emerge through neutral transitions Although a separate theory altogether the emphasis on neutrality as a process whereby neutral alleles are randomly fixed by genetic drift finds some inspiration from the earlier attempt by the neutral theory to invoke its importance in evolution 34 Conceptually there are two components A and B which may represent two proteins which interact with each other A which performs a function for the system does not depend on its interaction with B for its functionality and the interaction itself may have randomly arisen in an individual with the ability to disappear without an effect on the fitness of A This present yet currently unnecessary interaction is therefore called an excess capacity of the system However a mutation may occur which compromises the ability of A to perform its function independently However the A B interaction that has already emerged sustains the capacity of A to perform its initial function Therefore the emergence of the A B interaction presuppresses the deleterious nature of the mutation making it a neutral change in the genome that is capable of spreading through the population via random genetic drift Hence A has gained a dependency on its interaction with B 35 In this case the loss of B or the A B interaction would have a negative effect on fitness and so purifying selection would eliminate individuals where this occurs While each of these steps are individually reversible for example A may regain the capacity to function independently or the A B interaction may be lost a random sequence of mutations tends to further reduce the capacity of A to function independently and a random walk through the dependency space may very well result in a configuration in which a return to functional independence of A is far too unlikely to occur which makes CNE a one directional or ratchet like process 36 CNE which does not invoke adaptationist mechanisms for the origins of more complex systems which involve more parts and interactions contributing to the whole has seen application in the understanding of the evolutionary origins of the spliceosomal eukaryotic complex RNA editing additional ribosomal proteins beyond the core the emergence of long noncoding RNA from junk DNA and so forth 37 38 39 40 In some cases ancestral sequence reconstruction techniques have afforded the ability for experimental demonstration of some proposed examples of CNE as in heterooligomeric ring protein complexes in some fungal lineages 41 CNE has also been put forwards as the null hypothesis for explaining complex structures and thus adaptationist explanations for the emergence of complexity must be rigorously tested on a case by case basis against this null hypothesis prior to acceptance Grounds for invoking CNE as a null include that it does not presume that changes offered an adaptive benefit to the host or that they were directionally selected for while maintaining the importance of more rigorous demonstrations of adaptation when invoked so as to avoid the excessive flaws of adaptationism criticized by Gould and Lewontin 42 3 43 Empirical evidence for the neutral theory editPredictions derived from the neutral theory are generally supported in studies of molecular evolution 44 One of corollaries of the neutral theory is that the efficiency of positive selection is higher in populations or species with higher effective population sizes 45 This relationship between the effective population size and selection efficiency was evidenced by genomic studies of species including chimpanzee and human 45 and domesticated species 46 In small populations e g a population bottleneck during a speciation event slightly deleterious mutations should accumulate Data from various species supports this prediction in that the ratio of nonsynonymous to synonymous nucleotide substitutions between species generally exceeds that within species 31 In addition nucleotide and amino acid substitutions generally accumulate over time in a linear fashion which is consistent with neutral theory 44 Arguments against the neutral theory cite evidence of widespread positive selection and selective sweeps in genomic data 47 Empirical support for the neutral theory may vary depending on the type of genomic data studied and the statistical tools used to detect positive selection 44 For example Bayesian methods for the detection of selected codon sites and McDonald Kreitman tests have been criticized for their rate of erroneous identification of positive selection 31 44 See also editAdaptive evolution in the human genome Coalescent theory Evolution of biological complexity Masatoshi Nei Molecular evolution Tomoko Ohta Unified 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Charlesworth B January 2019 The importance of the Neutral Theory in 1968 and 50 years on A response to Kern and Hahn 2018 Evolution International Journal of Organic Evolution 73 1 111 114 doi 10 1111 evo 13650 PMC 6496948 PMID 30460993 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Ohta T December 2002 Near neutrality in evolution of genes and gene regulation Proceedings of the National Academy of Sciences of the United States of America 99 25 16134 7 Bibcode 2002PNAS 9916134O doi 10 1073 pnas 252626899 PMC 138577 PMID 12461171 Ohta Tomoko 1973 Slightly Deleterious Mutant Substitutions in Evolution Nature 246 5428 96 98 Bibcode 1973Natur 246 96O doi 10 1038 246096a0 ISSN 1476 4687 PMID 4585855 S2CID 4226804 Kimura Motoo 1983 The neutral theory of molecular evolution Cambridge University Press ISBN 978 0 521 31793 1 a b c d Hughes Austin L 2008 Near Neutrality the leading edge of the Neutral Theory of Molecular 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doi 10 1002 bies 201100010 PMID 21381061 S2CID 205470421 Stoltzfus Arlin 2012 10 13 Constructive neutral evolution exploring evolutionary theory s curious disconnect Biology Direct 7 1 35 doi 10 1186 1745 6150 7 35 ISSN 1745 6150 PMC 3534586 PMID 23062217 Gray Michael W Lukes Julius Archibald John M Keeling Patrick J Doolittle W Ford 2010 11 12 Irremediable Complexity Science 330 6006 920 921 Bibcode 2010Sci 330 920G doi 10 1126 science 1198594 ISSN 0036 8075 PMID 21071654 S2CID 206530279 Lukes Julius Archibald John M Keeling Patrick J Doolittle W Ford Gray Michael W 2011 How a neutral evolutionary ratchet can build cellular complexity IUBMB Life 63 7 528 537 doi 10 1002 iub 489 PMID 21698757 S2CID 7306575 Lamech Lilian T Mallam Anna L Lambowitz Alan M 2014 12 23 Herschlag Daniel ed Evolution of RNA Protein Interactions Non Specific Binding Led to RNA Splicing Activity of Fungal Mitochondrial Tyrosyl tRNA Synthetases PLOS Biology 12 12 e1002028 doi 10 1371 journal pbio 1002028 ISSN 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Nei Masatoshi Suzuki Yoshiyuki Nozawa Masafumi 2010 09 01 The Neutral Theory of Molecular Evolution in the Genomic Era Annual Review of Genomics and Human Genetics 11 1 265 289 doi 10 1146 annurev genom 082908 150129 ISSN 1527 8204 PMID 20565254 a b Bakewell Margaret A Shi Peng Zhang Jianzhi May 2007 More genes underwent positive selection in chimpanzee evolution than in human evolution Proceedings of the National Academy of Sciences 104 18 7489 7494 Bibcode 2007PNAS 104 7489B doi 10 1073 pnas 0701705104 ISSN 0027 8424 PMC 1863478 PMID 17449636 Chen Jianhai Ni Pan Li Xinyun Han Jianlin Jakovlic Ivan Zhang Chengjun Zhao Shuhong 2018 01 19 Population size may shape the accumulation of functional mutations following domestication BMC Evolutionary Biology 18 1 4 Bibcode 2018BMCEE 18 4C doi 10 1186 s12862 018 1120 6 ISSN 1471 2148 PMC 5775542 PMID 29351740 Kern Andrew D Hahn Matthew W 2018 06 01 Kumar Sudhir ed The Neutral Theory in Light of Natural Selection Molecular Biology and Evolution 35 6 1366 1371 doi 10 1093 molbev msy092 ISSN 0737 4038 PMC 5967545 PMID 29722831 External links editMisconceptions about natural selection and adaptation the neutral theory at http evolution berkeley edu Celebrating 50 years of the Neutral Theory Molecular Biology and Evolution July 2018 Retrieved from https en wikipedia org w index php title Neutral theory of molecular evolution amp oldid 1220958775, wikipedia, wiki, book, books, library,

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