Selectionism and Neutralism in Molecular Evolution

Charles Darwin proposed that evolution occurs primarily by natural selection, but this view has been controversial from the beginning. Two of the major opposing views have been mutationism and neutralism. Early molecular studies suggested that most amino acid substitutions in proteins are neutral or...

Full description

Saved in:

Bibliographic Details
Published in	Molecular biology and evolution Vol. 22; no. 12; pp. 2318 - 2342
Main Author	Nei, Masatoshi
Format	Journal Article
Language	English
Published	United States Society for Molecular Biology and Evolution 01.12.2005
Subjects	Animals Evolution, Molecular Gene Expression Genetic Drift Genetic Variation Multigene Family Mutation Phenotype Phylogeny Polymorphism, Genetic Review Selection, Genetic neo-Darwinism neutral evolution multigene families positive selection neomutationism new genetic systems
Online Access	Get full text

Cover

Loading…

Abstract	Charles Darwin proposed that evolution occurs primarily by natural selection, but this view has been controversial from the beginning. Two of the major opposing views have been mutationism and neutralism. Early molecular studies suggested that most amino acid substitutions in proteins are neutral or nearly neutral and the functional change of proteins occurs by a few key amino acid substitutions. This suggestion generated an intense controversy over selectionism and neutralism. This controversy is partially caused by Kimura's definition of neutrality, which was too strict \batchmode \documentclass[fleqn,10pt,legalpaper]{article} \usepackage{amssymb} \usepackage{amsfonts} \usepackage{amsmath} \pagestyle{empty} \begin{document} $({\vert}2Ns{\vert}{\leq}1).$ \end{document} If we define neutral mutations as the mutations that do not change the function of gene products appreciably, many controversies disappear because slightly deleterious and slightly advantageous mutations are engulfed by neutral mutations. The ratio of the rate of nonsynonymous nucleotide substitution to that of synonymous substitution is a useful quantity to study positive Darwinian selection operating at highly variable genetic loci, but it does not necessarily detect adaptively important codons. Previously, multigene families were thought to evolve following the model of concerted evolution, but new evidence indicates that most of them evolve by a birth-and-death process of duplicate genes. It is now clear that most phenotypic characters or genetic systems such as the adaptive immune system in vertebrates are controlled by the interaction of a number of multigene families, which are often evolutionarily related and are subject to birth-and-death evolution. Therefore, it is important to study the mechanisms of gene family interaction for understanding phenotypic evolution. Because gene duplication occurs more or less at random, phenotypic evolution contains some fortuitous elements, though the environmental factors also play an important role. The randomness of phenotypic evolution is qualitatively different from allele frequency changes by random genetic drift. However, there is some similarity between phenotypic and molecular evolution with respect to functional or environmental constraints and evolutionary rate. It appears that mutation (including gene duplication and other DNA changes) is the driving force of evolution at both the genic and the phenotypic levels.
AbstractList	Charles Darwin proposed that evolution occurs primarily by natural selection, but this view has been controversial from the beginning. Two of the major opposing views have been mutationism and neutralism. Early molecular studies suggested that most amino acid substitutions in proteins are neutral or nearly neutral and the functional change of proteins occurs by a few key amino acid substitutions. This suggestion generated an intense controversy over selectionism and neutralism. This controversy is partially caused by Kimura's definition of neutrality, which was too strict (\|2Ns\|< or =1). If we define neutral mutations as the mutations that do not change the function of gene products appreciably, many controversies disappear because slightly deleterious and slightly advantageous mutations are engulfed by neutral mutations. The ratio of the rate of nonsynonymous nucleotide substitution to that of synonymous substitution is a useful quantity to study positive Darwinian selection operating at highly variable genetic loci, but it does not necessarily detect adaptively important codons. Previously, multigene families were thought to evolve following the model of concerted evolution, but new evidence indicates that most of them evolve by a birth-and-death process of duplicate genes. It is now clear that most phenotypic characters or genetic systems such as the adaptive immune system in vertebrates are controlled by the interaction of a number of multigene families, which are often evolutionarily related and are subject to birth-and-death evolution. Therefore, it is important to study the mechanisms of gene family interaction for understanding phenotypic evolution. Because gene duplication occurs more or less at random, phenotypic evolution contains some fortuitous elements, though the environmental factors also play an important role. The randomness of phenotypic evolution is qualitatively different from allele frequency changes by random genetic drift. However, there is some similarity between phenotypic and molecular evolution with respect to functional or environmental constraints and evolutionary rate. It appears that mutation (including gene duplication and other DNA changes) is the driving force of evolution at both the genic and the phenotypic levels. Charles Darwin proposed that evolution occurs primarily by natural selection, but this view has been controversial from the beginning. Two of the major opposing views have been mutationism and neutralism. Early molecular studies suggested that most amino acid substitutions in proteins are neutral or nearly neutral and the functional change of proteins occurs by a few key amino acid substitutions. This suggestion generated an intense controversy over selectionism and neutralism. This controversy is partially caused by Kimura's definition of neutrality, which was too strict (\|2 Ns \| ≤ 1). If we define neutral mutations as the mutations that do not change the function of gene products appreciably, many controversies disappear because slightly deleterious and slightly advantageous mutations are engulfed by neutral mutations. The ratio of the rate of nonsynonymous nucleotide substitution to that of synonymous substitution is a useful quantity to study positive Darwinian selection operating at highly variable genetic loci, but it does not necessarily detect adaptively important codons. Previously, multigene families were thought to evolve following the model of concerted evolution, but new evidence indicates that most of them evolve by a birth-and-death process of duplicate genes. It is now clear that most phenotypic characters or genetic systems such as the adaptive immune system in vertebrates are controlled by the interaction of a number of multigene families, which are often evolutionarily related and are subject to birth-and-death evolution. Therefore, it is important to study the mechanisms of gene family interaction for understanding phenotypic evolution. Because gene duplication occurs more or less at random, phenotypic evolution contains some fortuitous elements, though the environmental factors also play an important role. The randomness of phenotypic evolution is qualitatively different from allele frequency changes by random genetic drift. However, there is some similarity between phenotypic and molecular evolution with respect to functional or environmental constraints and evolutionary rate. It appears that mutation (including gene duplication and other DNA changes) is the driving force of evolution at both the genic and the phenotypic levels. Charles Darwin proposed that evolution occurs primarily by natural selection, but this view has been controversial from the beginning. Two of the major opposing views have been mutationism and neutralism. Early molecular studies suggested that most amino acid substitutions in proteins are neutral or nearly neutral and the functional change of proteins occurs by a few key amino acid substitutions. This suggestion generated an intense controversy over selectionism and neutralism. This controversy is partially caused by Kimura's definition of neutrality, which was too strict [Formula: see text] If we define neutral mutations as the mutations that do not change the function of gene products appreciably, many controversies disappear because slightly deleterious and slightly advantageous mutations are engulfed by neutral mutations. The ratio of the rate of nonsynonymous nucleotide substitution to that of synonymous substitution is a useful quantity to study positive Darwinian selection operating at highly variable genetic loci, but it does not necessarily detect adaptively important codons. Previously, multigene families were thought to evolve following the model of concerted evolution, but new evidence indicates that most of them evolve by a birth-and-death process of duplicate genes. It is now clear that most phenotypic characters or genetic systems such as the adaptive immune system in vertebrates are controlled by the interaction of a number of multigene families, which are often evolutionarily related and are subject to birth-and-death evolution. Therefore, it is important to study the mechanisms of gene family interaction for understanding phenotypic evolution. Because gene duplication occurs more or less at random, phenotypic evolution contains some fortuitous elements, though the environmental factors also play an important role. The randomness of phenotypic evolution is qualitatively different from allele frequency changes by random genetic drift. However, there is some similarity between phenotypic and molecular evolution with respect to functional or environmental constraints and evolutionary rate. It appears that mutation (including gene duplication and other DNA changes) is the driving force of evolution at both the genic and the phenotypic levels. Charles Darwin proposed that evolution occurs primarily by natural selection, but this view has been controversial from the beginning. Two of the major opposing views have been mutationism and neutralism. Early molecular studies suggested that most amino acid substitutions in proteins are neutral or nearly neutral and the functional change of proteins occurs by a few key amino acid substitutions. This suggestion generated an intense controversy over selectionism and neutralism. This controversy is partially caused by Kimura's definition of neutrality, which was too strict (\|2Ns\|< or =1). If we define neutral mutations as the mutations that do not change the function of gene products appreciably, many controversies disappear because slightly deleterious and slightly advantageous mutations are engulfed by neutral mutations. The ratio of the rate of nonsynonymous nucleotide substitution to that of synonymous substitution is a useful quantity to study positive Darwinian selection operating at highly variable genetic loci, but it does not necessarily detect adaptively important codons. Previously, multigene families were thought to evolve following the model of concerted evolution, but new evidence indicates that most of them evolve by a birth-and-death process of duplicate genes. It is now clear that most phenotypic characters or genetic systems such as the adaptive immune system in vertebrates are controlled by the interaction of a number of multigene families, which are often evolutionarily related and are subject to birth-and-death evolution. Therefore, it is important to study the mechanisms of gene family interaction for understanding phenotypic evolution. Because gene duplication occurs more or less at random, phenotypic evolution contains some fortuitous elements, though the environmental factors also play an important role. The randomness of phenotypic evolution is qualitatively different from allele frequency changes by random genetic drift. However, there is some similarity between phenotypic and molecular evolution with respect to functional or environmental constraints and evolutionary rate. It appears that mutation (including gene duplication and other DNA changes) is the driving force of evolution at both the genic and the phenotypic levels.Charles Darwin proposed that evolution occurs primarily by natural selection, but this view has been controversial from the beginning. Two of the major opposing views have been mutationism and neutralism. Early molecular studies suggested that most amino acid substitutions in proteins are neutral or nearly neutral and the functional change of proteins occurs by a few key amino acid substitutions. This suggestion generated an intense controversy over selectionism and neutralism. This controversy is partially caused by Kimura's definition of neutrality, which was too strict (\|2Ns\|< or =1). If we define neutral mutations as the mutations that do not change the function of gene products appreciably, many controversies disappear because slightly deleterious and slightly advantageous mutations are engulfed by neutral mutations. The ratio of the rate of nonsynonymous nucleotide substitution to that of synonymous substitution is a useful quantity to study positive Darwinian selection operating at highly variable genetic loci, but it does not necessarily detect adaptively important codons. Previously, multigene families were thought to evolve following the model of concerted evolution, but new evidence indicates that most of them evolve by a birth-and-death process of duplicate genes. It is now clear that most phenotypic characters or genetic systems such as the adaptive immune system in vertebrates are controlled by the interaction of a number of multigene families, which are often evolutionarily related and are subject to birth-and-death evolution. Therefore, it is important to study the mechanisms of gene family interaction for understanding phenotypic evolution. Because gene duplication occurs more or less at random, phenotypic evolution contains some fortuitous elements, though the environmental factors also play an important role. The randomness of phenotypic evolution is qualitatively different from allele frequency changes by random genetic drift. However, there is some similarity between phenotypic and molecular evolution with respect to functional or environmental constraints and evolutionary rate. It appears that mutation (including gene duplication and other DNA changes) is the driving force of evolution at both the genic and the phenotypic levels. Charles Darwin proposed that evolution occurs primarily by natural selection, but this view has been controversial from the beginning. Two of the major opposing views have been mutationism and neutralism. Early molecular studies suggested that most amino acid substitutions in proteins are neutral or nearly neutral and the functional change of proteins occurs by a few key amino acid substitutions. This suggestion generated an intense controversy over selectionism and neutralism. This controversy is partially caused by Kimura's definition of neutrality, which was too strict \batchmode \documentclass[fleqn,10pt,legalpaper]{article} \usepackage{amssymb} \usepackage{amsfonts} \usepackage{amsmath} \pagestyle{empty} \begin{document} $({\vert}2Ns{\vert}{\leq}1).$ \end{document} If we define neutral mutations as the mutations that do not change the function of gene products appreciably, many controversies disappear because slightly deleterious and slightly advantageous mutations are engulfed by neutral mutations. The ratio of the rate of nonsynonymous nucleotide substitution to that of synonymous substitution is a useful quantity to study positive Darwinian selection operating at highly variable genetic loci, but it does not necessarily detect adaptively important codons. Previously, multigene families were thought to evolve following the model of concerted evolution, but new evidence indicates that most of them evolve by a birth-and-death process of duplicate genes. It is now clear that most phenotypic characters or genetic systems such as the adaptive immune system in vertebrates are controlled by the interaction of a number of multigene families, which are often evolutionarily related and are subject to birth-and-death evolution. Therefore, it is important to study the mechanisms of gene family interaction for understanding phenotypic evolution. Because gene duplication occurs more or less at random, phenotypic evolution contains some fortuitous elements, though the environmental factors also play an important role. The randomness of phenotypic evolution is qualitatively different from allele frequency changes by random genetic drift. However, there is some similarity between phenotypic and molecular evolution with respect to functional or environmental constraints and evolutionary rate. It appears that mutation (including gene duplication and other DNA changes) is the driving force of evolution at both the genic and the phenotypic levels.
Author	Nei, Masatoshi
Author_xml	– sequence: 1 givenname: Masatoshi surname: Nei fullname: Nei, Masatoshi
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/16120807$$D View this record in MEDLINE/PubMed
BookMark	eNqFkc1LxDAQxYOsuOvq0avsSbxUM03TJBdBFr9g1YN6Dtl2qpG0WZt2wf_elvoN4ikJ85s3L_O2yajyFRKyB_QIqGLHpXdLXB-XwcZJvEEmwJmIQIAakQkV3T2hTI7JdgjPlEKSpOkWGUMKMZVUTEh8hw6zxvrKhnJmqnx2g21TG9c_bTW79l25daaena29a3twh2wWxgXcfT-n5OH87H5-GS1uL67mp4so48CbCClditiwmBUCpFGx5JArXihVQJpBQQETKCQimkRkzMBScBkzmvOcSyUpm5KTQXfVLkvMM6x6X3pV29LUr9obq39WKvukH_1aAwcGUnQCB-8CtX9pMTS6tCFD50yFvg06lUKlqeD_gqCYEFSoDtz_bunTy8c-OyAagKz2IdRYfCFU93npIS895NXx7Bef2cb0W-5-ZN2fXYdDl29X_wx4A8Mhqmo
CitedBy_id	crossref_primary_10_1093_molbev_msn126 crossref_primary_10_1073_pnas_0703349104 crossref_primary_10_1002_evan_21347 crossref_primary_10_1371_journal_pgen_1004328 crossref_primary_10_1093_molbev_msn123 crossref_primary_10_1007_s11692_015_9315_x crossref_primary_10_1111_eva_12620 crossref_primary_10_1155_2015_984706 crossref_primary_10_1534_genetics_111_133454 crossref_primary_10_1016_j_csbj_2024_05_037 crossref_primary_10_1093_gbe_evr057 crossref_primary_10_1073_pnas_1406556111 crossref_primary_10_1196_annals_1438_001 crossref_primary_10_1371_journal_pone_0000324 crossref_primary_10_1016_j_actatropica_2012_05_010 crossref_primary_10_1093_jhered_esr097 crossref_primary_10_1042_BCJ20160577 crossref_primary_10_1111_nph_19633 crossref_primary_10_1186_s12864_023_09717_3 crossref_primary_10_1111_mmi_15341 crossref_primary_10_1371_journal_pgen_1001164 crossref_primary_10_1371_journal_pone_0038958 crossref_primary_10_1002_path_2461 crossref_primary_10_1098_rspb_2009_2084 crossref_primary_10_1016_j_ympev_2008_06_008 crossref_primary_10_1002_eji_202149383 crossref_primary_10_1073_pnas_1304227110 crossref_primary_10_1007_s00343_012_1252_2 crossref_primary_10_1007_s00239_018_9880_6 crossref_primary_10_1093_molbev_mss025 crossref_primary_10_3390_genes13091615 crossref_primary_10_1038_msb4100152 crossref_primary_10_1002_ajpa_21439 crossref_primary_10_1186_s12862_016_0637_9 crossref_primary_10_1093_molbev_msn224 crossref_primary_10_3389_fphys_2018_01966 crossref_primary_10_1007_s00439_020_02208_5 crossref_primary_10_1016_j_biotechadv_2020_107572 crossref_primary_10_1038_s41598_017_01490_0 crossref_primary_10_1111_j_1558_5646_2010_00969_x crossref_primary_10_1093_molbev_msq176 crossref_primary_10_1111_evo_14423 crossref_primary_10_1016_j_gene_2013_09_114 crossref_primary_10_1371_journal_pone_0130161 crossref_primary_10_1186_1471_2148_11_89 crossref_primary_10_1097_FPC_0b013e3282f9b68e crossref_primary_10_1080_07391102_2020_1748717 crossref_primary_10_1111_mec_13948 crossref_primary_10_3389_fcimb_2017_00413 crossref_primary_10_1371_journal_pcbi_1002005 crossref_primary_10_1002_ece3_400 crossref_primary_10_3724_SP_J_1005_2008_00483 crossref_primary_10_1002_jmv_26598 crossref_primary_10_1590_0074_02760200620 crossref_primary_10_2307_25065847 crossref_primary_10_1590_S1415_47572014000300004 crossref_primary_10_1111_jeb_13419 crossref_primary_10_1186_1471_2148_8_269 crossref_primary_10_2976_1_2739115_10_2976_1 crossref_primary_10_1002_cplx_20387 crossref_primary_10_1016_j_gene_2008_06_024 crossref_primary_10_1038_s41559_017_0237_0 crossref_primary_10_3390_ijms252413710 crossref_primary_10_1209_0295_5075_134_28002 crossref_primary_10_1534_genetics_104_75135 crossref_primary_10_1007_s10739_019_09583_4 crossref_primary_10_1016_j_cell_2019_12_015 crossref_primary_10_1093_molbev_msr120 crossref_primary_10_1093_gbe_evab290 crossref_primary_10_1371_journal_pone_0156739 crossref_primary_10_1080_00028487_2011_621813 crossref_primary_10_1525_bio_2012_62_11_3 crossref_primary_10_3390_genes13061036 crossref_primary_10_1111_mec_12957 crossref_primary_10_1016_j_drudis_2009_09_006 crossref_primary_10_1126_science_1255274 crossref_primary_10_3389_fgene_2022_903240 crossref_primary_10_1007_s00251_017_1028_0 crossref_primary_10_1073_pnas_1411012111 crossref_primary_10_1073_pnas_0901855106 crossref_primary_10_1093_molbev_msq165 crossref_primary_10_1016_j_tig_2009_01_002 crossref_primary_10_1016_j_tpb_2018_11_005 crossref_primary_10_1093_molbev_msq138 crossref_primary_10_1186_1471_2164_9_312 crossref_primary_10_1007_s00427_006_0089_0 crossref_primary_10_1073_pnas_0710150104 crossref_primary_10_3389_fphys_2019_01172 crossref_primary_10_1155_2010_568375 crossref_primary_10_1007_s12064_010_0091_y crossref_primary_10_1186_1471_2148_11_305 crossref_primary_10_1016_j_fsi_2015_01_030 crossref_primary_10_1016_j_jtbi_2008_12_029 crossref_primary_10_1186_1745_6150_8_24 crossref_primary_10_1038_s41579_023_00852_y crossref_primary_10_1007_s11295_010_0340_8 crossref_primary_10_1007_s43657_021_00017_y crossref_primary_10_1104_pp_112_212324 crossref_primary_10_1093_molbev_msz075 crossref_primary_10_1007_s00251_007_0205_y crossref_primary_10_1016_j_meegid_2008_07_002 crossref_primary_10_1038_s41598_019_53291_2 crossref_primary_10_1007_s00442_021_05054_y crossref_primary_10_1111_are_13751 crossref_primary_10_1111_brv_13010 crossref_primary_10_3389_fgene_2022_831068 crossref_primary_10_3390_nu1020276 crossref_primary_10_1073_pnas_0913970107 crossref_primary_10_1093_molbev_mss095 crossref_primary_10_1093_gbe_evu288 crossref_primary_10_1016_j_tig_2009_07_004 crossref_primary_10_1007_s00251_010_0440_5 crossref_primary_10_1007_s11191_017_9935_x crossref_primary_10_1073_pnas_0701572104 crossref_primary_10_3390_ani13020288 crossref_primary_10_1093_gbe_evp038 crossref_primary_10_1111_mec_17365 crossref_primary_10_1038_nrg2480 crossref_primary_10_1134_S0006297918040089 crossref_primary_10_1534_genetics_107_079046 crossref_primary_10_1007_s13238_013_0004_1 crossref_primary_10_1007_s11434_008_0202_z crossref_primary_10_1016_j_meegid_2017_01_010 crossref_primary_10_1016_j_jtbi_2011_01_025 crossref_primary_10_1186_s12862_015_0516_9 crossref_primary_10_1186_1471_2105_8_63 crossref_primary_10_1093_ve_vev025 crossref_primary_10_1093_molbev_msq122 crossref_primary_10_1063_1_4871365 crossref_primary_10_1016_j_gene_2007_03_017 crossref_primary_10_1093_molbev_msp129 crossref_primary_10_1162_ARTL_a_00150 crossref_primary_10_1371_journal_pgen_1001315 crossref_primary_10_1007_s12304_018_9333_z crossref_primary_10_1016_j_physa_2023_128569 crossref_primary_10_1111_mec_13559 crossref_primary_10_1038_nrg2473 crossref_primary_10_1007_s00338_007_0206_1 crossref_primary_10_1111_j_1558_5646_2008_00560_x crossref_primary_10_1080_14888386_2007_9712822 crossref_primary_10_1101_gr_074674_107 crossref_primary_10_1093_molbev_msp019 crossref_primary_10_1159_000499664 crossref_primary_10_1073_pnas_2120037119 crossref_primary_10_1093_nar_gkaa1268 crossref_primary_10_1103_PhysRevE_111_015427 crossref_primary_10_1371_journal_pone_0000283 crossref_primary_10_1038_s41598_024_74061_9 crossref_primary_10_1016_j_bse_2011_05_016 crossref_primary_10_1007_s10682_011_9537_z crossref_primary_10_1007_s11033_009_9925_4 crossref_primary_10_1093_gbe_evae198 crossref_primary_10_1073_pnas_0901522106 crossref_primary_10_3389_fnhum_2016_00509 crossref_primary_10_1016_j_gene_2012_12_096 crossref_primary_10_1534_genetics_107_082792 crossref_primary_10_1073_pnas_1004823107 crossref_primary_10_1111_jpy_12882 crossref_primary_10_1126_scisignal_2003768 crossref_primary_10_1016_j_jtbi_2018_01_004 crossref_primary_10_1007_s10709_007_9179_9 crossref_primary_10_1002_ece3_10365 crossref_primary_10_1073_pnas_0705658104 crossref_primary_10_1038_sj_hdy_6801094 crossref_primary_10_1186_s12863_014_0124_5 crossref_primary_10_1111_j_1744_7909_2008_00786_x crossref_primary_10_1016_j_meegid_2008_04_003 crossref_primary_10_1111_1755_0998_13969 crossref_primary_10_1016_j_forsciint_2010_09_011 crossref_primary_10_1016_j_ygeno_2020_06_039 crossref_primary_10_1101_gr_3681406 crossref_primary_10_1371_journal_pone_0001472 crossref_primary_10_2976_1_2739116_10_2976_1 crossref_primary_10_1186_gb_2011_12_3_r26 crossref_primary_10_1093_molbev_msn179 crossref_primary_10_1007_s12031_014_0327_2 crossref_primary_10_1111_j_1558_5646_2010_01054_x crossref_primary_10_1073_pnas_0607105104 crossref_primary_10_1007_s11033_011_0930_z crossref_primary_10_1038_hdy_2011_97 crossref_primary_10_1016_j_tpb_2014_11_004 crossref_primary_10_1186_s12864_016_3058_7 crossref_primary_10_1186_1471_2148_10_49 crossref_primary_10_1038_s41564_019_0412_y crossref_primary_10_1111_mec_13513 crossref_primary_10_1073_pnas_0702207104 crossref_primary_10_1146_annurev_marine_050823_104415 crossref_primary_10_3389_fmars_2018_00393 crossref_primary_10_1098_rspa_2018_0238 crossref_primary_10_1590_S1415_47572009005000025 crossref_primary_10_1016_j_drudis_2010_10_007 crossref_primary_10_1093_molbev_msn143 crossref_primary_10_1016_j_compbiolchem_2011_08_001 crossref_primary_10_1016_j_jmb_2009_11_075 crossref_primary_10_1007_s10709_012_9689_y crossref_primary_10_1103_PhysRevE_96_012414 crossref_primary_10_1016_j_jtbi_2022_111236 crossref_primary_10_1111_j_1749_7345_2011_00492_x crossref_primary_10_1021_acs_biochem_6b00818 crossref_primary_10_1007_s00239_005_0291_0 crossref_primary_10_1093_molbev_msy149 crossref_primary_10_1155_2009_725049 crossref_primary_10_1146_annurev_genom_082908_150129 crossref_primary_10_1093_ismejo_wrad035 crossref_primary_10_1186_1936_6434_6_22 crossref_primary_10_1007_s12052_008_0094_z
ContentType	Journal Article
Copyright	The Author 2005. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oupjournals.org 2005
Copyright_xml	– notice: The Author 2005. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oupjournals.org 2005
DBID	AAYXX CITATION CGR CUY CVF ECM EIF NPM 8FD FR3 P64 RC3 7X8 5PM
DOI	10.1093/molbev/msi242
DatabaseName	CrossRef Medline MEDLINE MEDLINE (Ovid) MEDLINE MEDLINE PubMed Technology Research Database Engineering Research Database Biotechnology and BioEngineering Abstracts Genetics Abstracts MEDLINE - Academic PubMed Central (Full Participant titles)
DatabaseTitle	CrossRef MEDLINE Medline Complete MEDLINE with Full Text PubMed MEDLINE (Ovid) Genetics Abstracts Engineering Research Database Technology Research Database Biotechnology and BioEngineering Abstracts MEDLINE - Academic
DatabaseTitleList	MEDLINE Genetics Abstracts MEDLINE - Academic
Database_xml	– sequence: 1 dbid: NPM name: PubMed url: https://proxy.k.utb.cz/login?url=http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed sourceTypes: Index Database – sequence: 2 dbid: EIF name: MEDLINE url: https://proxy.k.utb.cz/login?url=https://www.webofscience.com/wos/medline/basic-search sourceTypes: Index Database
DeliveryMethod	fulltext_linktorsrc
Discipline	Biology
EISSN	1537-1719
EndPage	2342
ExternalDocumentID	PMC1513187 16120807 10_1093_molbev_msi242 10.1093/molbev/msi242
Genre	Journal Article Research Support, N.I.H., Extramural
GrantInformation_xml	– fundername: NIGMS NIH HHS grantid: R01 GM020293-33A2 – fundername: NIGMS NIH HHS grantid: R01 GM020293 – fundername: NIGMS NIH HHS grantid: GM020293
GroupedDBID	--- -E4 -~X .2P .GJ .I3 .ZR 0R~ 18M 1TH 29M 2WC 4.4 48X 53G 5VS 5WA 70D 7X7 AAFWJ AAIJN AAIMJ AAJKP AAJQQ AAMDB AAMVS AAOGV AAPNW AAPQZ AAPXW AAUQX AAVAP AAVLN ABEJV ABEUO ABGNP ABIXL ABKDP ABLJU ABNKS ABPTD ABQLI ABQTQ ABSMQ ABTAH ABXVV ABZBJ ACGFO ACGFS ACIPB ACIWK ACMRT ACNCT ACPRK ACUFI ACUTO ACYTK ADBBV ADEYI ADEZT ADFTL ADGZP ADHKW ADHZD ADJQC ADOCK ADRIX ADRTK ADYVW ADZTZ ADZXQ AECKG AEGPL AEJOX AEKKA AEKSI AELWJ AEMDU AENEX AENZO AEPUE AETBJ AEWNT AFFNX AFIYH AFOFC AFPKN AFRAH AFULF AFXEN AGINJ AGKEF AGSYK AHMBA AHXPO AIAGR AIJHB AJEUX AKHUL AKWXX ALMA_UNASSIGNED_HOLDINGS ALTZX ALUQC AMNDL APIBT APWMN ARIXL ASAOO ATDFG AXUDD AYOIW AZVOD BAWUL BAYMD BCRHZ BEYMZ BHONS BQDIO BQUQU BSWAC BTQHN BTRTY BVRKM C1A CAG CDBKE COF CS3 CXTWN CZ4 DAKXR DFGAJ DIK DILTD DU5 D~K E3Z EBS EE~ EJD EMOBN F5P F9B FHSFR FLIZI FOTVD GAUVT GJXCC GROUPED_DOAJ GX1 H13 H5~ HAR HH5 HW0 HZ~ IAO IGS IHR IOX ITC J21 KOP KQ8 KSI KSN M-Z M49 MBTAY ML0 MVM N9A NGC NLBLG NMDNZ NOYVH NTWIH NU- O0~ O9- OAWHX ODMLO OJQWA OK1 OVD O~Y P2P PAFKI PEELM PQQKQ Q1. Q5Y RD5 RHF RNI ROL ROX ROZ RPM RUSNO RW1 RXO RZO TEORI TJP TJX TLC TN5 TOX TR2 VQA W8F WOQ X7H XJT XSW YAYTL YHZ YKOAZ YXANX ZCA ZCG ZKX ZXP ZY4 ~02 ~91 AAYXX BBNVY CITATION 88E 8AO 8FI 8FJ 8G5 ABUWG AEUYN AFKRA AZQEC BENPR BHPHI CCPQU CGR CUY CVF DWQXO ECM EIF FYUFA GNUQQ GUQSH HCIFZ HMCUK M1P M2O M7P NPM PSQYO UKHRP 8FD FR3 P64 RC3 7X8 5PM
ID	FETCH-LOGICAL-c515t-e00b72a323f718a92851d95f99f16c1f01e41f8eeea47c3a1b758230d5d589803
IEDL.DBID	TOX
ISSN	0737-4038
IngestDate	Thu Aug 21 18:33:43 EDT 2025 Fri Jul 11 11:03:20 EDT 2025 Fri Jul 11 15:29:05 EDT 2025 Thu Apr 03 07:00:02 EDT 2025 Tue Jul 01 00:48:55 EDT 2025 Thu Apr 24 22:51:26 EDT 2025 Fri Feb 07 10:35:36 EST 2025
IsDoiOpenAccess	false
IsOpenAccess	true
IsPeerReviewed	true
IsScholarly	true
Issue	12
Keywords	neo-Darwinism neutral evolution multigene families positive selection neomutationism new genetic systems
Language	English
LinkModel	DirectLink
MergedId	FETCHMERGED-LOGICAL-c515t-e00b72a323f718a92851d95f99f16c1f01e41f8eeea47c3a1b758230d5d589803
Notes	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 E-mail: nxm2@psu.edu.
OpenAccessLink	https://academic.oup.com/mbe/article-pdf/22/12/2318/6152210/msi242.pdf
PMID	16120807
PQID	19377079
PQPubID	23462
PageCount	25
ParticipantIDs	pubmedcentral_primary_oai_pubmedcentral_nih_gov_1513187 proquest_miscellaneous_68796675 proquest_miscellaneous_19377079 pubmed_primary_16120807 crossref_primary_10_1093_molbev_msi242 crossref_citationtrail_10_1093_molbev_msi242 oup_primary_10_1093_molbev_msi242
ProviderPackageCode	CITATION AAYXX
PublicationCentury	2000
PublicationDate	2005-12-01
PublicationDateYYYYMMDD	2005-12-01
PublicationDate_xml	– month: 12 year: 2005 text: 2005-12-01 day: 01
PublicationDecade	2000
PublicationPlace	United States
PublicationPlace_xml	– name: United States
PublicationTitle	Molecular biology and evolution
PublicationTitleAlternate	Mol Biol Evol
PublicationYear	2005
Publisher	Society for Molecular Biology and Evolution
Publisher_xml	– name: Society for Molecular Biology and Evolution
References	Mol Biol Evol. 2006 May;23(5):1095
References_xml	– reference: - Mol Biol Evol. 2006 May;23(5):1095
SSID	ssj0014466
Score	2.3211684
SecondaryResourceType	review_article
Snippet	Charles Darwin proposed that evolution occurs primarily by natural selection, but this view has been controversial from the beginning. Two of the major...
SourceID	pubmedcentral proquest pubmed crossref oup
SourceType	Open Access Repository Aggregation Database Index Database Enrichment Source Publisher
StartPage	2318
SubjectTerms	Animals Evolution, Molecular Gene Expression Genetic Drift Genetic Variation Multigene Family Mutation Phenotype Phylogeny Polymorphism, Genetic Review Selection, Genetic
Title	Selectionism and Neutralism in Molecular Evolution
URI	https://www.ncbi.nlm.nih.gov/pubmed/16120807 https://www.proquest.com/docview/19377079 https://www.proquest.com/docview/68796675 https://pubmed.ncbi.nlm.nih.gov/PMC1513187
Volume	22
hasFullText	1
inHoldings	1
isFullTextHit
isPrint
link	http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwjV3dS8MwEA8yEHwRv52fFcQny5qmaZpHkY0hbD64wd5K0iY42Dqx28D_3kvTzlUd-lh6oeXuyP3uLvkdQreelkxrFboSp4kbUJ64XGDuBsKnWmIq09RcTu71w-4weBrRUVnvyH9p4XPSms4mUi1b03wM4QQ2WwjAhiR_8DxatQuqpiQjDBIiEpVkmj9W14JP7ULbGq78fjxyLd509tBuCRSdB2vZfbSlsgO0bUdHfhwi_6UYYGOqqfnUEVnq9NWiqFrA4zhzetXYW6e9LL3rCA077cFj1y3nH7gJoIy5qzxPMl8Qn2iIIIL7gI5STjXnGocJ1h5WAdaRUkoELCECSwD_kFKkNKURjzxyjBrZLFOnyElDJTUTWHMVmLAV-ZoxTaIQAECktN9E95Vi4qQkBzczKiaxbVKT2OoxtnpsoruV-JtlxdgkeANa_kvmurJBDL5tGhYiU7NFHgO4ZIbBb7NEGDHI1xhtohNrs69PAXQDNMyaiNWsuRIwvNr1N9n4teDXBhAEOx07-8e_n6Mdy-VqzrdcoMb8faEuAaXM5VXhoZ8VfOkX
linkProvider	Oxford University Press
openUrl	ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.atitle=Selectionism+and+neutralism+in+molecular+evolution&rft.jtitle=Molecular+biology+and+evolution&rft.au=Nei%2C+Masatoshi&rft.date=2005-12-01&rft.issn=0737-4038&rft.volume=22&rft.issue=12&rft.spage=2318&rft_id=info:doi/10.1093%2Fmolbev%2Fmsi242&rft.externalDBID=NO_FULL_TEXT
thumbnail_l	http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=0737-4038&client=summon
thumbnail_m	http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=0737-4038&client=summon
thumbnail_s	http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=0737-4038&client=summon