Genomic island of divergence during speciation and its underlying mechanisms

doi:10.17520/biods.2021383

Abstract

Abstract:

Background & Aims Understanding the mechanisms underlying the formation of species is a major task of ecological and evolutionary studies. Aided by the rapid development of sequencing technologies during the last two decades, a growing body of research has revealed a heterogeneous genomic landscape of divergence with the existence of genomic islands of divergence between closely related taxa. This pattern was interpreted as evidence for the speciation-with-gene-flow model, and genomic islands in divergence landscape were hypothesized to be caused by divergent selection in the face of gene flow. However, genomic islands can also arise from other evolutionary processes, such as introgression, divergent sorting of ancient polymorphisms, and linked selection. Previous empirical studies often focused on part of evolutionary processes when discerning the mechanism governing the formation of genomic islands. Therefore, this paper aims to clarify genomic island of divergence and related concepts, summarize the pros and cons of different methods of identifying genomic islands, compare the predicted properties of genomic islands of divergence under different evolutionary processes, and propose a research route for discerning the mechanism contributing to genomic islands during speciation. This paper may provide a guide for future studies on genomic islands and their underlying mechanisms.

Progress In recent years, various empirical and model-based approaches have been proposed to identify genomic islands. After comparing the pros and cons of these approaches, we think the significance test on observed F_ST using the null distribution of F_ST under different recombination rate according to the inferred best-fitting demographic model is the most reasonable. Based on similarities and differences of the predicted properties of genomic islands of divergence under different evolutionary processes, we point out the necessity of exploiting multiple indicators, such as introgression level, absolute divergence (d_XY), relative node depth (RND), and recombination rate, when discerning the mechanism contributing to genomic islands during speciation.

Prospects We suggest more attention should be paid to the ecological and genetic basis of reproductive isolation after discerning the mechanism underlying the formation of genomic islands. Meanwhile, future researches should be standardized to facilitate integrative analysis in a comparative framework, thus improving our understandings of the frequency of speciation with gene flow in the natural world.

Key words: speciation, gene flow, F_ST, genomic landscape of divergence, population genome

Qiong Sun, Rong Wang, Xiaoyong Chen. Genomic island of divergence during speciation and its underlying mechanisms[J]. Biodiv Sci, 2022, 30(3): 21383.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2021383

https://www.biodiversity-science.net/EN/Y2022/V30/I3/21383

Figures/Tables 5

References 101

[1]	Ackiss AS, Larson WA, Stott W (2020) Genotyping-by-sequen-cing illuminates high levels of divergence among sympatric forms of coregonines in the Laurentian Great Lakes. Evolutionary Applications, 13, 1037-1054. DOI URL
[2]	Aeschbacher S, Selby JP, Willis JH, Coop G (2017) Population-genomic inference of the strength and timing of selection against gene flow. Proceedings of the National Academy of Sciences, USA, 114, 7061-7066.
[3]	Andrew RL, Rieseberg LH (2013) Divergence is focused on few genomic regions early in speciation: Incipient speciation of sunflower ecotypes. Evolution, 67, 2468-2482. DOI PMID
[4]	Battey CJ (2020) Evidence of linked selection on the Z chromosome of hybridizing hummingbirds. Evolution, 74, 725- 739. DOI URL
[5]	Beaumont MA, Nichols RA (1996) Evaluating loci for use in the genetic analysis of population structure. Proceedings of the Royal Society of London Series B: Biological Sciences, 263, 1619-1626.
[6]	Behrens KA, Girasek QL, Sickler A, Hyde J, Buonaccorsi VP (2021) Regions of genetic divergence in depth-separated Sebastes rockfish species pairs: Depth as a potential driver of speciation. Molecular Ecology, 30, 4259-4275. DOI URL
[7]	Berg PR, Jentoft S, Star B, Ring KH, Knutsen H, Lien S, Jakobsen KS, André C (2015) Adaptation to low salinity promotes genomic divergence in Atlantic cod (Gadus morhua L.). Genome Biology and Evolution, 7, 1644-1663. DOI URL
[8]	Booker TR, Yeaman S, Whitlock MC (2020) Variation in recombination rate affects detection of outliers in genome scans under neutrality. Molecular Ecology, 29, 4274-4279. DOI URL
[9]	Bradbury IR, Hubert S, Higgins B, Bowman S, Borza T, Paterson IG, Snelgrove PVR, Morris CJ, Gregory RS, Hardie D, Hutchings JA, Ruzzante DE, Taggart CT, Bentzen P (2013) Genomic islands of divergence and their consequences for the resolution of spatial structure in an exploited marine fish. Evolutionary Applications, 6, 450-461. DOI PMID
[10]	Burri R (2017) Interpreting differentiation landscapes in the light of long-term linked selection. Evolution Letters, 1, 118-131. DOI URL
[11]	Burri R, Nater A, Kawakami T, Mugal CF, Olason PI, Smeds L, Suh A, Dutoit L, Bureš S, Garamszegi LZ, Hogner S, Moreno J, Qvarnström A, Ružić M, Sæther SA, Sætre GP, Török J, Ellegren H (2015) Linked selection and recombination rate variation drive the evolution of the genomic landscape of differentiation across the speciation continuum of Ficedula flycatchers. Genome Research, 25, 1656-1665. DOI PMID
[12]	Campagna L, Repenning M, Silveira LF, Fontana CS, Tubaro PL, Lovette IJ (2017) Repeated divergent selection on pigmentation genes in a rapid finch radiation. Science Advances, 3, e1602404.
[13]	Charlesworth B (1998) Measures of divergence between populations and the effect of forces that reduce variability. Molecular Biology and Evolution, 15, 538-543. PMID
[14]	Charlesworth B, Morgan MT, Charlesworth D (1993) The effect of deleterious mutations on neutral molecular variation. Genetics, 134, 1289-1303. DOI PMID
[15]	Charlesworth B, Nordborg M, Charlesworth D (1997) The effects of local selection, balanced polymorphism and background selection on equilibrium patterns of genetic diversity in subdivided populations. Genetical Research, 70, 155-174. DOI URL
[16]	Cheng X, Li LL, Xiao Y, Chen XY, Hu XS (2020) Advances in the methods of detecting interspecific gene introgression and their applications. Scientia Sinica Vita, 50, 1388-1404. (in Chinese with English abstract)
	[ 程祥, 李玲玲, 肖钰, 陈晓阳, 胡新生 (2020) 种间基因渐渗检测方法及其应用研究进展. 中国科学: 生命科学, 50, 1388-1404.]
[17]	Choi JY, Purugganan M, Stacy EA (2020) Divergent selection and primary gene flow shape incipient speciation of a riparian tree on Hawaii Island. Molecular Biology and Evolution, 37, 695-710. DOI URL
[18]	Costello MJ, May RM, Stork NE (2013) Can we name earth’s species before they go extinct? Science, 339, 413-416. DOI PMID
[19]	Cruickshank TE, Hahn MW (2014) Reanalysis suggests that genomic islands of speciation are due to reduced diversity, not reduced gene flow. Molecular Ecology, 23, 3133-3157. DOI PMID
[20]	Cutter AD, Payseur BA (2013) Genomic signatures of selection at linked sites: Unifying the disparity among species. Nature Reviews Genetics, 14, 262-274. DOI PMID
[21]	Ellegren H, Smeds L, Burri R, Olason PI, Backström N, Kawakami T, Künstner A, Mäkinen H, Nadachowska-Brzyska K, Qvarnström A, Uebbing S, Wolf JBW (2012) The genomic landscape of species divergence in Ficedula flycatchers. Nature, 491, 756-760. DOI URL
[22]	Excoffier L, Dupanloup I, Huerta-Sánchez E, Sousa VC, Foll M (2013) Robust demographic inference from genomic and SNP data. PLoS Genetics, 9, e1003905.
[23]	Excoffier L, Hofer T, Foll M (2009) Detecting loci under selection in a hierarchically structured population. Heredity, 103, 285-298. DOI PMID
[24]	Feder JL, Egan SP, Nosil P (2012a) The genomics of speciation-with-gene-flow. Trends in Genetics, 28, 342-350. DOI URL
[25]	Feder JL, Gejji R, Yeaman S, Nosil P (2012b) Establishment of new mutations under divergence and genome hitchhiking. Philosophical Transactions of the Royal Society of London Series B: Biological Sciences, 367, 461-474.
[26]	Feder JL, Nosil P (2010) The efficacy of divergence hitchhiking in generating genomic islands during ecological speciation. Evolution, 64, 1729-1747. DOI URL
[27]	Feder JL, Xie XF, Rull J, Velez S, Forbes A, Leung B, Dambroski H, Filchak KE, Aluja M (2005) Mayr, Dobzhansky, and Bush and the complexities of sympatric speciation in Rhagoletis. Proceedings of the National Academy of Sciences, USA, 102, 6573-6580.
[28]	Feulner PGD, Chain FJJ, Panchal M, Huang Y, Eizaguirre C, Kalbe M, Lenz TL, Samonte IE, Stoll M, Bornberg-Bauer E, Reusch TBH, Milinski M (2015) Genomics of divergence along a continuum of parapatric population differentiation. PLoS Genetics, 11, e1004966.
[29]	Foll M, Gaggiotti O (2008) A genome-scan method to identify selected loci appropriate for both dominant and codominant markers: A Bayesian perspective. Genetics, 180, 977-993. DOI URL
[30]	Gao F, Li HP (2016) Application of computer simulators in population genetics. Hereditas (Beijing), 38, 707-717. (in Chinese with English abstract)
	[ 高峰, 李海鹏 (2016) 群体遗传学模拟软件应用现状. 遗传, 38, 707-717.]
[31]	Guerrero RF, Hahn MW (2017) Speciation as a sieve for ancestral polymorphism. Molecular Ecology, 26, 5362-5368. DOI PMID
[32]	Gutenkunst RN, Hernandez RD, Williamson SH, Bustamante CD (2009) Inferring the joint demographic history of multiple populations from multidimensional SNP frequency data. PLoS Genetics, 5, e1000695.
[33]	Han F, Lamichhaney S, Grant BR, Grant PR, Andersson L, Webster MT (2017) Gene flow, ancient polymorphism, and ecological adaptation shape the genomic landscape of divergence among Darwin’s finches. Genome Research, 27, 1004-1015. DOI URL
[34]	Harr B (2006) Genomic islands of differentiation between house mouse subspecies. Genome Research, 16, 730-737. DOI URL
[35]	Harrison RG (2012) The language of speciation. Evolution, 66, 3643-3657. DOI PMID
[36]	Harrison RG, Larson EL (2014) Hybridization, introgression, and the nature of species boundaries. Journal of Heredity, 105, 795-809. DOI URL
[37]	Hedrick PW (2013) Adaptive introgression in animals: Examples and comparison to new mutation and standing variation as sources of adaptive variation. Molecular Ecology, 22, 4606-4618. DOI PMID
[38]	Hirase S, Yamasaki YY, Sekino M, Nishisako M, Ikeda M, Hara M, Merilä J, Kikuchi K (2021) Genomic evidence for speciation with gene flow in broadcast spawning marine invertebrates. Molecular Biology and Evolution, 38, 4683-4699. DOI URL
[39]	Hofer T, Foll M, Excoffier L (2012) Evolutionary forces shaping genomic islands of population differentiation in humans. BMC Genomics, 13, 107. DOI URL
[40]	Hudson AG, Vonlanthen P, Bezault E, Seehausen O (2013) Genomic signatures of relaxed disruptive selection associated with speciation reversal in whitefish. BMC Evolutionary Biology, 13, 108. DOI PMID
[41]	Hudson RR, Slatkin M, Maddison WP (1992) Estimation of levels of gene flow from DNA sequence data. Genetics, 132, 583-589. DOI PMID
[42]	Irwin DE, Milá B, Toews DPL, Brelsford A, Kenyon HL, Porter AN, Grossen C, Delmore KE, Alcaide M, Irwin JH (2018) A comparison of genomic islands of differentiation across three young avian species pairs. Molecular Ecology, 27, 4839-4855. DOI URL
[43]	Larson WA, Dann TH, Limborg MT, McKinney GJ, Seeb JE, Seeb LW (2019) Parallel signatures of selection at genomic islands of divergence and the major histocompatibility complex in ecotypes of sockeye salmon across Alaska. Molecular Ecology, 28, 2254-2271. DOI URL
[44]	Larson WA, Limborg MT, McKinney GJ, Schindler DE, Seeb JE, Seeb LW (2017) Genomic islands of divergence linked to ecotypic variation in sockeye salmon. Molecular Ecology, 26, 554-570. DOI URL
[45]	Lyu HM, Zhou RC, Shi SH (2015) Recent advances in the study of ecological speciation. Biodiversity Science, 23, 398-407. (in Chinese with English abstract) DOI URL
	[ 吕昊敏, 周仁超, 施苏华 (2015) 生态物种形成及其研究进展. 生物多样性, 23, 398-407.] DOI
[46]	Ma T, Wang K, Hu QJ, Xi ZX, Wan DS, Wang Q, Feng JJ, Jiang DC, Ahani H, Abbott RJ, Lascoux M, Nevo E, Liu JQ (2018) Ancient polymorphisms and divergence hitchhiking contribute to genomic islands of divergence within a poplar species complex. Proceedings of the National Academy of Sciences, USA, 115, E236-E243.
[47]	Malinsky M, Challis RJ, Tyers AM, Schiffels S, Terai Y, Ngatunga BP, Miska EA, Durbin R, Genner MJ, Turner GF (2015) Genomic islands of speciation separate cichlid ecomorphs in an East African crater lake. Science, 350, 1493-1498. DOI PMID
[48]	Malinsky M, Matschiner M, Svardal H (2021) Dsuite - Fast D-statistics and related admixture evidence from VCF files. Molecular Ecology Resources, 21, 584-595. DOI PMID
[49]	Mallet J, Meyer A, Nosil P, Feder JL (2009) Space, sympatry and speciation. Journal of Evolutionary Biology, 22, 2332- 2341. DOI PMID
[50]	Mao JF, Ma YP, Zhou RC (2017) Approaches used to detect and test hybridization: Combining phylogenetic and population genetic analyses. Biodiversity Science, 25, 577-599. (in Chinese with English abstract) DOI URL
	[ 毛建丰, 马永鹏, 周仁超 (2017) 结合系统发育与群体遗传学分析检验杂交是否存在的技术策略. 生物多样性, 25, 577-599.] DOI
[51]	Marques DA, Lucek K, Meier JI, Mwaiko S, Wagner CE, Excoffier L, Seehausen O (2016) Genomics of rapid incipient speciation in sympatric threespine stickleback. PLoS Genetics, 12, e1005887.
[52]	Martin SH, Davey JW, Jiggins CD (2015) Evaluating the use of ABBA-BABA statistics to locate introgressed loci. Molecular Biology and Evolution, 32, 244-257. DOI PMID
[53]	Mayr E (1942) Systematics and the Origin of Species. Columbia University Press, New York.
[54]	McCulloch GA, Foster BJ, Dutoit L, Harrop TWR, Guhlin J, Dearden PK, Waters JM (2021) Genomics reveals widespread ecological speciation in flightless insects. Systematic Biology, 70, 863-876. DOI PMID
[55]	Michel AP, Guelbeogo WM, Grushko O, Schemerhorn BJ, Kern M, Willard MB, Sagnon NF, Costantini C, Besansky NJ (2005) Molecular differentiation between chromosomally defined incipient species of Anopheles funestus. Insect Molecular Biology, 14, 375-387. PMID
[56]	Michel AP, Sim S, Powell THQ, Taylor MS, Nosil P, Feder JL (2010) Widespread genomic divergence during sympatric speciation. Proceedings of the National Academy of Sciences, USA, 107, 9724-9729.
[57]	Mora C, Tittensor DP, Adl S, Simpson AGB, Worm B (2011) How many species are there on Earth and in the ocean? PLoS Biology, 9, e1001127.
[58]	Morales HE, Pavlova A, Amos N, Major R, Kilian A, Greening C, Sunnucks P (2018) Concordant divergence of mitogenomes and a mitonuclear gene cluster in bird lineages inhabiting different climates. Nature Ecology & Evolution, 2, 1258-1267.
[59]	Mořkovský L, Janoušek V, Reif J, Rídl J, Pačes J, Choleva L, Janko K, Nachman MW, Reifová R (2018) Genomic islands of differentiation in two songbird species reveal candidate genes for hybrid female sterility. Molecular Ecology, 27, 949-958. DOI PMID
[60]	Nachman MW, Payseur BA (2012) Recombination rate variation and speciation: Theoretical predictions and empirical results from rabbits and mice. Philosophical Transactions of the Royal Society of London Series B: Biological Sciences, 367, 409-421.
[61]	Nadeau NJ, Whibley A, Jones RT, Davey JW, Dasmahapatra KK, Baxter SW, Quail MA, Joron M ffrench-Constant RH, Blaxter ML, Mallet J, Jiggins CD (2012) Genomic islands of divergence in hybridizing Heliconius butterflies identified by large-scale targeted sequencing. Philosophical Transactions of the Royal Society of London Series B: Biological Sciences, 367, 343-353.
[62]	Nei M (1987) Molecular Evolutionary Genetics. Columbia University Press, New York.
[63]	Noor MAF, Bennett SM (2009) Islands of speciation or mirages in the desert? Examining the role of restricted recombination in maintaining species. Heredity, 103, 439-444. DOI PMID
[64]	Nosil P (2008) Speciation with gene flow could be common. Molecular Ecology, 17, 2103-2106. DOI URL
[65]	Nosil P (2012) Ecological Speciation. Oxford University Press, New York.
[66]	Nosil P, Egan SP, Funk DJ (2008) Heterogeneous genomic differentiation between walking-stick ecotypes: “Isolation by adaptation” and multiple roles for divergent selection. Evolution, 62, 316-336. DOI URL
[67]	Nosil P, Feder JL (2012) Genomic divergence during speciation: Causes and consequences. Philosophical Transactions of the Royal Society of London Series B: Biological Sciences, 367, 332-342.
[68]	Nosil P, Funk DJ, Ortiz-Barrientos D (2009) Divergent selection and heterogeneous genomic divergence. Molecular Ecology, 18, 375-402. DOI URL
[69]	Oziolor EM, Reid NM, Yair S, Lee KM, Guberman VerPloeg S, Bruns PC, Shaw JR, Whitehead A, Matson CW (2019) Adaptive introgression enables evolutionary rescue from extreme environmental pollution. Science, 364, 455-457. DOI PMID
[70]	Papadopulos AST, Igea J, Dunning LT, Osborne OG, Quan XP, Pellicer J, Turnbull C, Hutton I, Baker WJ, Butlin RK, Savolainen V (2019) Ecological speciation in sympatric palms: 3. Genetic map reveals genomic islands underlying species divergence in Howea. Evolution, 73, 1986-1995. DOI PMID
[71]	Peñalba JV, Wolf JBW (2020) From molecules to populations: Appreciating and estimating recombination rate variation. Nature Reviews Genetics, 21, 476-492. DOI PMID
[72]	Pfeifer B, Kapan DD (2019) Estimates of introgression as a function of pairwise distances. BMC Bioinformatics, 20, 207. DOI URL
[73]	Poelstra JW, Vijay N, Bossu CM, Lantz H, Ryll B, Müller I, Baglione V, Unneberg P, Wikelski M, Grabherr MG, Wolf JBW (2014) The genomic landscape underlying phenotypic integrity in the face of gene flow in crows. Science, 344, 1410-1414. DOI PMID
[74]	Racimo F, Sankararaman S, Nielsen R, Huerta-Sánchez E (2015) Evidence for archaic adaptive introgression in humans. Nature Reviews Genetics, 16, 359-371. DOI URL
[75]	Ravinet M, Faria R, Butlin RK, Galindo J, Bierne N, Rafajlović M, Noor MAF, Mehlig B, Westram AM (2017) Interpreting the genomic landscape of speciation: A road map for finding barriers to gene flow. Journal of Evolutionary Biology, 30, 1450-1477. DOI PMID
[76]	Renaut S, Grassa CJ, Yeaman S, Moyers BT, Lai Z, Kane NC, Bowers JE, Burke JM, Rieseberg LH (2013) Genomic islands of divergence are not affected by geography of speciation in sunflowers. Nature Communications, 4, 1827. DOI PMID
[77]	Rettelbach A, Nater A, Ellegren H (2019) How linked selection shapes the diversity landscape in Ficedula flycatchers. Genetics, 212, 277-285. DOI PMID
[78]	Richards EJ, Martin CH (2017) Adaptive introgression from distant Caribbean islands contributed to the diversification of a microendemic adaptive radiation of trophic specialist pupfishes. PLoS Genetics, 13, e1006919. DOI URL
[79]	Rosenzweig BK, Pease JB, Besansky NJ, Hahn MW (2016) Powerful methods for detecting introgressed regions from population genomic data. Molecular Ecology, 25, 2387-2397. DOI PMID
[80]	Rundle HD, Nosil P (2005) Ecological speciation. Ecology Letters, 8, 336-352. DOI URL
[81]	Sankararaman S, Mallick S, Dannemann M, Prüfer K, Kelso J, Pääbo S, Patterson N, Reich D (2014) The genomic landscape of Neanderthal ancestry in present-day humans. Nature, 507, 354-357. DOI URL
[82]	Semenov GA, Safran RJ, Smith CCR, Turbek SP, Mullen SP, Flaxman SM (2019) Unifying theoretical and empirical perspectives on genomic differentiation. Trends in Ecology & Evolution, 34, 987-995. DOI URL
[83]	Smadja CM, Butlin RK (2011) A framework for comparing processes of speciation in the presence of gene flow. Molecular Ecology, 20, 5123-5140. DOI URL
[84]	Smith JM, Haigh J (1974) The hitch-hiking effect of a favourable gene. Genetical Research, 23, 23-35. DOI URL
[85]	Smith NGC, Fearnhead P (2005) A comparison of three estimators of the population-scaled recombination rate: Accuracy and robustness. Genetics, 171, 2051-2062. PMID
[86]	Soria-Carrasco V, Gompert Z, Comeault AA, Farkas TE, Parchman TL, Johnston JS, Buerkle CA, Feder JL, Bast J, Schwander T, Egan SP, Crespi BJ, Nosil P (2014) Stick insect genomes reveal natural selection’s role in parallel speciation. Science, 344, 738-742. DOI PMID
[87]	Stevison LS, McGaugh SE (2020) It’s time to stop sweeping recombination rate under the genome scan rug. Molecular Ecology, 29, 4249-4253.
[88]	Tavares H, Whibley A, Field DL, Bradley D, Couchman M, Copsey L, Elleouet J, Burrus M, Andalo C, Li MM, Li Q, Xue YB, Rebocho AB, Barton NH, Coen E (2018) Selection and gene flow shape genomic islands that control floral guides. Proceedings of the National Academy of Sciences, USA, 115, 11006-11011.
[89]	Teng HJ, Zhang YH, Shi CM, Mao FB, Cai WS, Lu L, Zhao FQ, Sun ZS, Zhang JX (2017) Population genomics reveals speciation and introgression between brown Norway rats and their sibling species. Molecular Biology and Evolution, 34, 2214-2228. DOI URL
[90]	Todesco M, Owens GL, Bercovich N, Légaré JS, Soudi S, Burge DO, Huang KC, Ostevik KL, Drummond EBM, Imerovski I, Lande K, Pascual-Robles MA, Nanavati M, Jahani M, Cheung W, Staton SE, Muños S, Nielsen R, Donovan LA, Burke JM, Yeaman S, Rieseberg LH (2020) Massive haplotypes underlie ecotypic differentiation in sunflowers. Nature, 584, 602-607. DOI URL
[91]	Tsumura Y, Uchiyama K, Moriguchi Y, Ueno S, Ihara-Ujino T (2012) Genome scanning for detecting adaptive genes along environmental gradients in the Japanese conifer, Cryptomeria japonica. Heredity, 109, 349-360. DOI PMID
[92]	Turner TL, Hahn MW, Nuzhdin SV (2005) Genomic islands of speciation in Anopheles gambiae. PLoS Biology, 3, e285. DOI URL
[93]	Via S (2009) Natural selection in action during speciation. Proceedings of the National Academy of Sciences, USA, 106, 9939-9946.
[94]	Vijay N, Bossu CM, Poelstra JW, Weissensteiner MH, Suh A, Kryukov AP, Wolf JBW (2016) Evolution of heterogeneous genome differentiation across multiple contact zones in a crow species complex. Nature Communications, 7, 13195. DOI URL
[95]	Wang BS, Mojica JP, Perera N, Lee CR, Lovell JT, Sharma A, Adam C, Lipzen A, Barry K, Rokhsar DS, Schmutz J, Mitchell-Olds T (2019) Ancient polymorphisms contribute to genome-wide variation by long-term balancing selection and divergent sorting in Boechera stricta. Genome Biology, 20, 126. DOI URL
[96]	Wang J, Street NR, Scofield DG, Ingvarsson PK (2016) Variation in linked selection and recombination drive genomic divergence during allopatric speciation of European and American aspens. Molecular Biology and Evolution, 33, 1754-1767. DOI URL
[97]	Wang ZF, Jiang YZ, Bi H, Lu ZQ, Ma YZ, Yang XY, Chen NN, Tian B, Liu BB, Mao XX, Ma T, DiFazio SP, Hu QJ, Abbott RJ, Liu JQ (2021) Hybrid speciation via inheritance of alternate alleles of parental isolating genes. Molecular Plant, 14, 208-222. DOI URL
[98]	Wolf JBW, Ellegren H (2017) Making sense of genomic islands of differentiation in light of speciation. Nature Reviews Genetics, 18, 87-100. DOI URL
[99]	Wu CI (2001) The genic view of the process of speciation. Journal of Evolutionary Biology, 14, 851-865. DOI URL
[100]	Wu CI, Ting CT (2004) Genes and speciation. Nature Reviews Genetics, 5, 114-122. DOI URL
[101]	Yeaman S, Aeschbacher S, Bürger R (2016) The evolution of genomic islands by increased establishment probability of linked alleles. Molecular Ecology, 25, 2542-2558. DOI PMID

方法 Methods	优点 Pros	缺点 Cons	示例文献 Example references
基于经验的方法 Empirical approach
固定/近固定差异的局部聚集程度 Extent of regional clustering of fixed/nearly fixed differences	非常简单便捷 Very simple and convenient	未充分考虑种群统计的影响; 仅使用固定/近固定差异的分子标记进行分析, 忽略了基因组中大量的其他变异信息 The effect of population demography is not fully considered; Only fixed or nearly fixed differences are used in the analysis, with numerous differences in the genome ignored	Turner et al, 2005; Harr, 2006
F_ST百分位数 Percentile of F_ST	非常简单便捷 Very simple and convenient	未充分考虑种群统计的影响 The effect of population demography is not fully considered	Renaut et al, 2013; Poelstra et al, 2014; Ma et al, 2018; Battey, 2020
Z标准化后的F_ST (ZF_ST)大小 Value of Z-transformed F_ST (ZF_ST)	非常简单便捷 Very simple and convenient	未充分考虑种群统计的影响 The effect of population demography is not fully considered	Han et al, 2017; Wang et al, 2019; Choi et al, 2020; Behrens et al, 2021
根据实际数据重抽样构造F_ST零分布检验观测F_ST的显著性 Significance test on observed F_ST using the null distribution of F_ST built by resampling real data	简单便捷 Simple and convenient	未充分考虑种群统计的影响 The effect of population demography is not fully considered	Michel et al, 2005; Nadeau et al, 2012; Berg et al, 2015; Feulner et al, 2015; Larson et al, 2017; Mořkovský et al, 2018; Ackiss et al, 2020
基于模型的方法 Model-based approach
隐马尔科夫模型 Hidden Markov model (HMM)	简单便捷; 无需设置滑窗大小, 考虑了相邻分子标记之间的非独立性 Simple and convenient; No need to set the sliding window size, and the non-independence among neighboring markers is modeled	未充分考虑种群统计的影响; 每种隐含状态对应观测值的分布、高/低分化水平两种隐含状态互相的转移概率是否为0等方面的假设对鉴定结果有一定影响 The effect of population demography is not fully considered; The identification result is affected by the assumptions such as the distribution of observations corresponding to each hidden state and whether the transition probability between the two hidden states of high/low divergence is 0	Turner et al, 2005; Hofer et al, 2012; Soria-Carrasco et al, 2014; Marques et al, 2016; Morales et al, 2018
BayeScan	简单便捷 Simple and convenient	当研究对象中有经历过严重瓶颈效应的种群时, 鉴定结果存在较高的假阳性率 High false positive rate when studied population underwent a strong bottleneck	Michel et al, 2010; Andrew & Rieseberg, 2013; Larson et al, 2019; McCulloch et al, 2021
根据假定的种群动态场景构建不同杂合度下F_ST的零分布检验观测F_ST的显著性 Significance test on observed F_ST using the null distribution of F_ST under different heterozygosity according to the assumed population demographic scenario	简单便捷; 相关软件内置了不同种群动态场景 Simple and convenient; Different population demographic models are built in related softwares	假定的种群动态场景可能与现实场景相差甚远, 导致假阳性率较高 The assumed population demographic model may be very different from the real scenario, resulting in a high false positive rate	Michel et al, 2010; Tsumura et al, 2012; Bradbury et al, 2013; Hudson et al, 2013
根据推断的最优种群统计模型构建F_ST的零分布检验观测F_ST的显著性 Significance test on observed F_ST using the null distribution of F_ST according to the inferred best-fitting demographic model	构造F_ST零分布时使用的种群统计模型更符合现实场景 The demographic model used to build the null distribution of F_ST is more realistic	步骤有些繁琐; 未考虑重组率对F_ST分布的影响 Somewhat complex; The effect of recombination rate on the distribution of F_ST is ignored	Malinsky et al, 2015; Wang et al, 2016
根据推断的最优种群统计模型构建不同重组率下F_ST的零分布检验观测F_ST的显著性 Significance test on observed F_ST using the null distribution of F_ST under different recombination rate according to the inferred best-fitting demographic model	构造F_ST零分布时使用的种群统计模型更符合现实场景; 考虑了重组率对F_ST分布的影响 The demographic model used to build the null distribution of F_ST is more realistic, and the effect of recombination rate on distribution of F_ST is considered	步骤繁琐 Complicated	目前尚无示例文献 No example reference is available yet

方法 Methods	优点 Pros	缺点 Cons	示例文献 Example references
基于经验的方法 Empirical approach
固定/近固定差异的局部聚集程度 Extent of regional clustering of fixed/nearly fixed differences	非常简单便捷 Very simple and convenient	未充分考虑种群统计的影响; 仅使用固定/近固定差异的分子标记进行分析, 忽略了基因组中大量的其他变异信息 The effect of population demography is not fully considered; Only fixed or nearly fixed differences are used in the analysis, with numerous differences in the genome ignored	Turner et al, 2005; Harr, 2006
F_ST百分位数 Percentile of F_ST	非常简单便捷 Very simple and convenient	未充分考虑种群统计的影响 The effect of population demography is not fully considered	Renaut et al, 2013; Poelstra et al, 2014; Ma et al, 2018; Battey, 2020
Z标准化后的F_ST (ZF_ST)大小 Value of Z-transformed F_ST (ZF_ST)	非常简单便捷 Very simple and convenient	未充分考虑种群统计的影响 The effect of population demography is not fully considered	Han et al, 2017; Wang et al, 2019; Choi et al, 2020; Behrens et al, 2021
根据实际数据重抽样构造F_ST零分布检验观测F_ST的显著性 Significance test on observed F_ST using the null distribution of F_ST built by resampling real data	简单便捷 Simple and convenient	未充分考虑种群统计的影响 The effect of population demography is not fully considered	Michel et al, 2005; Nadeau et al, 2012; Berg et al, 2015; Feulner et al, 2015; Larson et al, 2017; Mořkovský et al, 2018; Ackiss et al, 2020
基于模型的方法 Model-based approach
隐马尔科夫模型 Hidden Markov model (HMM)	简单便捷; 无需设置滑窗大小, 考虑了相邻分子标记之间的非独立性 Simple and convenient; No need to set the sliding window size, and the non-independence among neighboring markers is modeled	未充分考虑种群统计的影响; 每种隐含状态对应观测值的分布、高/低分化水平两种隐含状态互相的转移概率是否为0等方面的假设对鉴定结果有一定影响 The effect of population demography is not fully considered; The identification result is affected by the assumptions such as the distribution of observations corresponding to each hidden state and whether the transition probability between the two hidden states of high/low divergence is 0	Turner et al, 2005; Hofer et al, 2012; Soria-Carrasco et al, 2014; Marques et al, 2016; Morales et al, 2018
BayeScan	简单便捷 Simple and convenient	当研究对象中有经历过严重瓶颈效应的种群时, 鉴定结果存在较高的假阳性率 High false positive rate when studied population underwent a strong bottleneck	Michel et al, 2010; Andrew & Rieseberg, 2013; Larson et al, 2019; McCulloch et al, 2021
根据假定的种群动态场景构建不同杂合度下F_ST的零分布检验观测F_ST的显著性 Significance test on observed F_ST using the null distribution of F_ST under different heterozygosity according to the assumed population demographic scenario	简单便捷; 相关软件内置了不同种群动态场景 Simple and convenient; Different population demographic models are built in related softwares	假定的种群动态场景可能与现实场景相差甚远, 导致假阳性率较高 The assumed population demographic model may be very different from the real scenario, resulting in a high false positive rate	Michel et al, 2010; Tsumura et al, 2012; Bradbury et al, 2013; Hudson et al, 2013
根据推断的最优种群统计模型构建F_ST的零分布检验观测F_ST的显著性 Significance test on observed F_ST using the null distribution of F_ST according to the inferred best-fitting demographic model	构造F_ST零分布时使用的种群统计模型更符合现实场景 The demographic model used to build the null distribution of F_ST is more realistic	步骤有些繁琐; 未考虑重组率对F_ST分布的影响 Somewhat complex; The effect of recombination rate on the distribution of F_ST is ignored	Malinsky et al, 2015; Wang et al, 2016
根据推断的最优种群统计模型构建不同重组率下F_ST的零分布检验观测F_ST的显著性 Significance test on observed F_ST using the null distribution of F_ST under different recombination rate according to the inferred best-fitting demographic model	构造F_ST零分布时使用的种群统计模型更符合现实场景; 考虑了重组率对F_ST分布的影响 The demographic model used to build the null distribution of F_ST is more realistic, and the effect of recombination rate on distribution of F_ST is considered	步骤繁琐 Complicated	目前尚无示例文献 No example reference is available yet