Aim The genus Camellia is widely distributed, primarily in East Asia. Camellia japonica is located at the northern limit of this genus distribution, and elucidating its distribution changes is crucial for understanding the evolution of plants in this region, as well as their relationship with geological history and climate change. Also, the classification of sect. Camellia in Japan has not been clarified. Therefore, the aim of this study is to understand the evolutionary history of Japanese sect. Camellia. Location Japan, Korea, Taiwan, and the coastal area of China Taxon Camella (Theaceae). Methods The genetic population structure was analyzed by SNP data using MIG-seq. The relationship between Japanese sect. Camellia including the related species in China was further inferred from the phylogeny generated by RA x ML, SplitsTree and PCA. Population genetic structure was inferred using a Bayesian clustering method (ADMIXTURE). We then employed approximate Bayesian computation to explore the changes in population, asking which events best explain the phylogeographical signature. Ecological niche modeling was combined with genetic analyses to compare current and past distributions. Results The analyses consistently showed that C. japonica and C. rusticana are distinct, having diverged from each other between approximately 5.4 and 12 million years ago. Furthermore, C. japonica differentiated into four major populations (North, South, Ryukyu-Taiwan, and Continent). Main Conclusion Japanese sect. Camellia underwent speciation during archipelago formation, reflecting its ancient evolutionary history compared with other native Japanese plants. The conventional hypothesis that C. rusticana diverged from C. japonica in snow-rich environments under Quaternary period was rejected. Our results suggest that both species have been independent since ancient times, and that ancestral populations of C. japonica have persisted in northern regions. Furthermore, it is estimated that C. japonica population on the continent experienced a back-dispersal event from southern Japan during the late Pleistocene glaciation.

Geographic differences in floral traits may reflect geographic differences in effective pollinator assemblages. Independent local adaptation to pollinator assemblages in multiple regions would be expected to cause parallel floral trait evolution, although sufficient evidence for this is still lacking. In this study, we investigated the relationship between flower spur length and pollinator size in 16 populations of Aquilegia buergeriana var. buergeriana distributed in four mountain regions in the Japanese Alps. We also examined the genetic relationship between yellow- and red-flowered individuals, to see if color differences caused genetic differentiation by pollinator isolation. Genetic relationships among 16 populations were analyzed based on genome-wide single-nucleotide polymorphisms. Even among populations within the same mountain region, pollinator size varied widely, and the average spur length of A. buergeriana var. buergeriana in each population was strongly related to the average visitor size of that population. Genetic relatedness between populations was not related to the similarity of spur length between populations; rather, it was related to the geographic proximity of populations in each mountain region. Our results indicate that spur length in each population evolved independently of the population genetic structure but in parallel in different mountain regions. Further, yellow- and red-flowered individuals of A. buergeriana var. buergeriana were not genetically differentiated. Unlike other Aquilegia species in Europe and America visited by hummingbirds and hawkmoths, this species is consistently visited by bumblebees in Japan. As a result, genetic isolation by flower color has not occurred.