Contrasted histories of organelle and nuclear genomes underlying physiological diversification in a grass species
Data files
Oct 13, 2020 version files 17.12 MB
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alignment_mitogenomes.fasta
10.67 MB
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alignment_plastids.fasta
6.45 MB
Abstract
C4 photosynthesis evolved multiple times independently in angiosperms, but most origins are relatively old so that the early events linked to photosynthetic diversification are blurred. The grass Alloteropsis semialata is an exception, as this species encompasses C4 and non-C4 populations. Using phylogenomics and population genomics, we infer the history of dispersal and secondary gene flow before, during, and after photosynthetic divergence in A. semialata. We further analyse the genome composition of individuals with varied ploidy levels to establish the origins of polyploids in this species. Detailed organelle phylogenies indicate limited seed dispersal within the mountainous region of origin and the emergence of a C4 lineage after dispersal to warmer areas of lower elevation. Patterns of differentiation across nuclear genomes highlight repeated secondary gene flow. In particular, the nuclear genome associated with the C4 phenotype was swept into a distantly related maternal lineage probably via unidirectional pollen flow. Multiple segmental allopolyploidy events mediated additional secondary genetic exchanges between photosynthetic types. Overall, our results show that limited dispersal and isolation allowed lineage divergence, with photosynthetic innovation happening after migration to new environments, and pollen-mediated gene flow led to the rapid spread of the derived C4 physiology away from its region of origin.
Organelle genome alignments of 75 accessions of the grass Alloteropsis semialata. Refer to the manuscript for details on the methods used for organelle genome assembly.
The second inverted repeat of the plastid genomes was removed. Both alignments were trimmed to remove sites covered by less than 90% of individuals.