The best of both worlds: combining population genetic and quantitative genetic models. (English) Zbl 07702576
Summary: Numerous traits under migration-selection balance are shown to exhibit complex patterns of genetic architecture with large variance in effect sizes. However, the conditions under which such genetic architectures are stable have yet to be investigated, because studying the influence of a large number of small allelic effects on the maintenance of spatial polymorphism is mathematically challenging, due to the high complexity of the systems that arise. In particular, in the most simple case of a haploid population in a two-patch environment, while it is known from population genetics that polymorphism at a single major-effect locus is stable in the symmetric case, there exist no analytical predictions on how this polymorphism holds when a polygenic background also contributes to the trait. Here we propose to answer this question by introducing a new eco-evo methodology that allows us to take into account the combined contributions of a major-effect locus and of a quantitative background resulting from small-effect loci, where inheritance is encoded according to an extension to the infinitesimal model. In a regime of small variance contributed by the quantitative loci, we justify that traits are concentrated around the major alleles, according to a normal distribution, using new convex analysis arguments. This allows a reduction in the complexity of the system using a separation of time scales approach. We predict an undocumented phenomenon of loss of polymorphism at the major-effect locus despite strong selection for local adaptation, because the quantitative background slowly disrupts the rapidly established polymorphism at the major-effect locus, which is confirmed by individual-based simulations. Our study highlights how segregation of a quantitative background can greatly impact the dynamics of major-effect loci by provoking migrational meltdowns. We also provide a comprehensive toolbox designed to describe how to apply our method to more complex population genetic models.
MSC:
| 92-XX | Biology and other natural sciences |
Keywords:
quantitative genetics; population genetics; heterogeneous environment; genetic architecture; polymorphism; asymptotic analysisSoftware:
SLiM 2References:
| [1] | Barles, G.; Mirrahimi, S.; Perthame, B., Concentration in Lotka-Volterra parabolic or integral equations: A general convergence result, Methods Appl. Anal., 16, 3, 321-340 (2009), ISSN: 10732772, 19450001 · Zbl 1204.35027 |
| [2] | Barton, N. H.; Etheridge, A. M.; Véber, A., The infinitesimal model: Definition, derivation, and implications, Theor. Popul. Biol., 118, 50-73 (2017) · Zbl 1394.92082 |
| [3] | Bulmer, M. G., The effect of selection on genetic variability, Am. Nat., 105, 943, 201-211 (1971) |
| [4] | Bulmer, M. G., The Mathematical Theory of Quantitative Genetics (1980), Oxford University Press · Zbl 0441.92007 |
| [5] | Bürger, R.; Akerman, A., The effects of linkage and gene flow on local adaptation: A two-locus continent-island model, Theor. Popul. Biol., 80, 4, 272-288 (2011) · Zbl 1323.92126 |
| [6] | Calvez, V.; Garnier, J.; Patout, F., Asymptotic analysis of a quantitative genetics model with nonlinear integral operator, J. de L’École Polytechn., 6, 537-579 (2019) · Zbl 1420.35167 |
| [7] | Chevin, Luis-Miguel; Hospital, Frédéric, Selective sweep at a quantitative trait locus in the presence of background genetic variation, Genetics, 180, 3, 1645-1660 (2008) |
| [8] | de Vladar, Harold; Barton, Nick, Stability and response of polygenic traits to stabilizing selection and mutation, Genetics, 197, 2, 749-767 (2014) |
| [9] | Débarre, F.; Ronce, O.; Gandon, S., Quantifying the effects of migration and mutation on adaptation and demography in spatially heterogeneous environments, J. Evol. Biol., 26, 6, 1185-1202 (2013) |
| [10] | Dekens, Léonard, Evolutionary dynamics of complex traits in sexual populations in a heterogeneous environment: How normal?, J. Math. Biol., 84, 3, 15 (2022), ISSN: 0303-6812, 1432-1416 · Zbl 1492.35359 |
| [11] | Diekmann, O., The dynamics of adaptation: An illuminating example and a Hamilton-Jacobi approach, Theor. Popul. Biol., 67, 4, 257-271 (2005) · Zbl 1072.92035 |
| [12] | Fisher, R. A., The correlation between relatives on the supposition of Mendelian inheritance, Trans. R. Soc. Edinburgh, 52, 2, 399-433 (1919) |
| [13] | Gagnaire, Pierre-Alexandre; Gaggiotti, Oscar E., Detecting polygenic selection in marine populations by combining population genomics and quantitative genetics approaches, Current Zool., 62, 6, 603-616 (2016), ISSN: 1674-5507, 2396-9814 |
| [14] | Garnier, J., Adaptation to a changing environment: What me normal? (2022), BioRxiv, URL https://www.biorxiv.org/content/early/2022/06/26/2022.06.22.497192 |
| [15] | Geroldinger, Ludwig; Bürger, Reinhard, A two-locus model of spatially varying stabilizing or directional selection on a quantitative trait, Theor. Popul. Biol., 94, 10-41 (2014) |
| [16] | Groeters, Francis R.; Tabashnik, Bruce E., Roles of selection intensity, major genes, and minor genes in evolution of insecticide resistance, J. Econ. Entomol., 93, 6, 1580-1587 (2000) |
| [17] | Haller, Benjamin C.; Messer, Philipp W., SLiM 3: Forward Genetic Simulations Beyond the Wright-Fisher Model, Mol. Biol. Evol., 36, 3, 632-637 (2019), arXiv:https://academic.oup.com/mbe/article-pdf/36/3/632/27980602/msy228.pdf |
| [18] | Hamel, F.; Lavigne, F.; Roques, L., Adaptation in a heterogeneous environment I: Persistence versus extinction., J. Math. Biol. (2021) · Zbl 1473.35598 |
| [19] | Hendry, A. P.; Day, T.; Taylor, E. B., Population mixing and the adaptive divergence of quantitative traits in discrete populations: A theoretical framework for empirical tests, Evolution, 55, 3, 459-466 (2001) |
| [20] | Höllinger, Ilse; Pennings, Pleunia S.; Hermisson, Joachim, Polygenic adaptation: From sweeps to subtle frequency shifts, PLOS Genet., 15, 3, e1008035 (2019) |
| [21] | Jain, Kavita; Stephan, Wolfgang, Rapid adaptation of a polygenic trait after a sudden environmental shift, Genetics, 206, 1, 389-406 (2017) |
| [22] | Koch, Eva L., Genetic architecture of repeated phenotypic divergence in Littorina saxatilis ecotype evolution, Evolution, evo.14602 (2022), ISSN: 0014-3820, 1558-5646 |
| [23] | Lande, Russell, The response to selection on major and minor mutations affecting a metrical trait, Heredity, 50, 1, 47-65 (1983), ISSN: 0018-067X, 1365-2540 |
| [24] | Lange, K., Central limit theorems of pedigrees, J. Math. Biol., 6, 1, 59-66 (1978), ISSN: 0303-6812, 1432-1416 · Zbl 0388.92008 |
| [25] | Levin, J. J.; Levinson, N., Singular perturbations of non-linear systems of differential equations and an associated boundary layer equation, J. Ration. Mech. Anal., 3, 247-270 (1954), ISSN: 19435282, 19435290, URL http://www.jstor.org/stable/24900288 · Zbl 0055.08204 |
| [26] | Lythgoe, K. A., Consequences of gene flow in spatially structured populations, Genet. Res., 69, 1, 49-60 (1997) |
| [27] | McKenzie, John A.; Batterham, Philip, The genetic, molecular and phenotypic consequences of selection for insecticide resistance, Trends Ecol. Evol., 9, 5, 166-169 (1994), URL https://www.sciencedirect.com/science/article/pii/0169534794900795 |
| [28] | Mirrahimi, S., A Hamilton-Jacobi approach to characterize the evolutionary equilibria in heterogeneous environments, Math. Models Methods Appl. Sci., 27, 13, 2425-2460 (2017) · Zbl 1383.35108 |
| [29] | Mirrahimi, S.; Gandon, S., Evolution of specialization in heterogeneous environments: Equilibrium between selection, mutation and migration, Genetics, 214, 2, 479-491 (2020) |
| [30] | Nagylaki, T.; Lou, Y., Patterns of multiallelic polymorphism maintained by migration and selection, Theor. Popul. Biol., 59, 4, 297-313 (2001) · Zbl 1043.92025 |
| [31] | Orr, H. Allen, The population genetics of adaptation: The distribution of factors fixed during adaptive evolution, Evolution, 52, 4, 935-949 (1998) |
| [32] | Patout, The Cauchy problem for the infinitesimal model in the regime of small variance (2020), arXiv:2001.04682 |
| [33] | Perthame, B.; Barles, G., Dirac concentrations in Lotka-Volterra parabolic PDEs, Indiana Univ. Math. J., 57, 7, 3275-3302 (2008) · Zbl 1172.35005 |
| [34] | Porto-Neto, Laercio R., The genetic architecture of climatic adaptation of tropical cattle, PLoS One, 9, 11, Article e113284 pp. (2014) |
| [35] | Rockman, Matthew V., The QTN program and the alleles that matter for evolution: All that’s gold does not glitter, Evolution, 66, 1, 1-17 (2012) |
| [36] | Ronce, O.; Kirkpatrick, M., When sources become sinks: Migrational meltdown in heterogeneous habitats, Evolution, 55, 8, 1520-1531 (2001) |
| [37] | Slate, Jon, INVITED REVIEW: Quantitative trait locus mapping in natural populations: Progress, caveats and future directions, Mol. Ecol., 14, 2, 363-379 (2005) |
| [38] | Szép, Enikő; Sachdeva, Himani; Barton, N. H., Polygenic local adaptation in metapopulations: A stochastic eco-evolutionary model, Evolution, 75, 5, 1030-1045 (2021), URL https://onlinelibrary.wiley.com/doi/abs/10.1111/evo.14210 |
| [39] | Turelli, M.; Barton, N. H., Genetic and statistical analyses of strong selection on PolygenicTraits: What, me normal?, Genetics, 913-941 (1994) |
| [40] | Turner, Lex B., A genome-wide association study of tick burden and milk composition in cattle, Animal Prod. Sci., 50, 4, 235 (2010) |
| [41] | Walsh, B.; Lynch, M., Evolution and Selection of Quantitative Traits (2018), OUP Oxford, URL https://books.google.co.uk/books?id=L2liDwAAQBAJ |
| [42] | Yeaman, Sam, Evolution of polygenic traits under global vs local adaptation, Genetics, 220, 1, iyab134 (2022) |
| [43] | Yeaman, S.; Otto, S. P., Establishment and maintenance of adaptive genetic divergence under migration, selection and drift, Evolution, 65, 7, 2123-2129 (2011) |
| [44] | Yeaman, S.; Whitlock, M. C., The genetic architecture of adaptation under migration-selection balance: The genetic architecture of local adaptation, Evolution, 65, 7, 1897-1911 (2011) |
This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. In some cases that data have been complemented/enhanced by data from zbMATH Open. This attempts to reflect the references listed in the original paper as accurately as possible without claiming completeness or a perfect matching.
