Incipient allochronic speciation due to non-selective assortative mating by flowering time, mutation and genetic drift

Resurrection studies are a useful tool to measure how phenotypic traits have changed in populations and they allow testing whether these traits modifications are a response to selection caused by an environmental change. Selfing, through its reduction of effective size, could challenge the ability of a population to adapt to environmental changes. Here, we used a resurrection study to test for adaptation in a selfing population of Medicago truncatula, by comparing the genetic composition and flowering across 22 generations. We found evidence for evolution towards earlier flowering times by about two days and a peculiar genetic structure, typical for highly selfing population, where some multilocus genotypes (MLGs) are persistent through time. We used the change in frequency of the MLGs through time as a multilocus fitness measure and built a selection gradient that suggests evolution towards earlier flowering times. Yet, a simulation model revealed that the observed change in flowering time could be explained by drift alone, provided the effective size of the population is small enough (<150). These analyses suffer from the difficulty to estimate the effective size in a highly selfing population, where effective recombination is severely reduced.

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The evolution of flowering phenology: an example from the wind-pollinated African Restionaceae

Annals of Botany ◽

10.1093/aob/mcaa129 ◽

2020 ◽

Vol 126 (7) ◽

pp. 1141-1153

Author(s):

H Peter Linder

Keyword(s):

Climate Change ◽

Flowering Time ◽

Assortative Mating ◽

Adaptive Radiation ◽

Flowering Phenology ◽

Sister Species ◽

Evolutionary Pattern ◽

Environmental Correlates

Abstract Background and Aims Flowering phenology is arguably the most striking angiosperm phenophase. Although the response of species to climate change and the environmental correlates of the communities have received much attention, the interspecific evolution of flowering phenology has hardly been investigated. I explored this in the wind-pollinated dioecious Restionaceae (restios) of the hyperdiverse Cape flora, to disentangle the effects of phylogeny, traits, and biotic and abiotic environments on flowering time shifts. Methods I recorded the flowering times of 347 of the 351 species, mapped these over a 98 % complete phylogeny and inferred the evolutionary pattern and abiotic correlates of flowering time shifts. The patterns and biotic/abiotic correlates of restio community mean flowering time were explored using 934 plots. Key Results Restios flower throughout the year, with large spring and smaller autumn peaks. Species flowering time is evolutionarily labile, poorly explained by either the environment or traits of the species, with half of all sister species allochronic. Community mean flowering time is related to elevation, temperature and rainfall. Conclusions Flowering time shifts may result from assortative mating and allochronic speciation, possibly leading to non-adaptive radiation. However, community mean flowering time may be environmentally selected. Diversification of flowering time may be non-adaptive, but species could be filtered through survival in suitable communities.

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Assortative mating can help adaptation of flowering time to a changing climate: insights from a polygenic model

Journal of Evolutionary Biology ◽

10.1111/jeb.13786 ◽

2021 ◽

Author(s):

Claire Godineau ◽

Ophélie Ronce ◽

Céline Devaux

Keyword(s):

Flowering Time ◽

Assortative Mating ◽

Polygenic Model ◽

Changing Climate

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A program for representing and simulating population genetic phenomena

Genetics and Molecular Biology ◽

10.1590/s1415-47572000000100009 ◽

2000 ◽

Vol 23 (1) ◽

pp. 53-60 ◽

Cited By ~ 1

Author(s):

Paulo A.S. Nuin ◽

P.A. Otto

Keyword(s):

Gene Flow ◽

Computer Program ◽

Assortative Mating ◽

Genetic Drift ◽

Population Genetic ◽

Mating Systems ◽

Visual Basic ◽

Genotype Frequencies ◽

Selection Gene ◽

Ibm Pc

The paper describes a computer program for representing and simulating population genetic phenomena, such as the distribution of gene and genotype frequencies under different mating systems (panmixia, inbreeding and assortative mating systems) and under influence of evolution factors (mutation, selection, gene flow and genetic drift). The program was written in Visual Basic (Microsoft, Inc.) and is able to run in any IBM-PC compatible computer running Windows 3.1 or later versions.

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