Analysis of the giant genomes of Fritillaria (Liliaceae) indicates that a lack of DNA removal characterizes extreme expansions in genome size.

Plants exhibit an extraordinary range of genome sizes, varying by > 2000-fold between the smallest and largest recorded values. In the absence of polyploidy, changes in the amount of repetitive DNA (transposable elements and tandem repeats) are primarily responsible for genome size differences between species. However, there is ongoing debate regarding the relative importance of amplification of repetitive DNA versus its deletion in governing genome size. Using data from 454 sequencing, we analysed the most repetitive fraction of some of the largest known genomes for diploid plant species, from members of Fritillaria. We revealed that genomic expansion has not resulted from the recent massive amplification of just a handful of repeat families, as shown in species with smaller genomes. Instead, the bulk of these immense genomes is composed of highly heterogeneous, relatively low-abundance repeat-derived DNA, supporting a scenario where amplified repeats continually accumulate due to infrequent DNA removal. Our results indicate that a lack of deletion and low turnover of repetitive DNA are major contributors to the evolution of extremely large genomes and show that their size cannot simply be accounted for by the activity of a small number of high-abundance repeat families.

Evolutionary relationships in the medicinally important genus Fritillaria L. (Liliaceae).

Fritillaria (Liliaceae) is a genus of approximately 140 species of bulbous perennial plants that includes taxa of both horticultural and medicinal importance. As well as being commercially valuable, Fritillaria species have attracted attention because of their exceptionally large genome sizes, with all values recorded to date in excess of 30Gb. Despite such interest in the genus, phylogenetic relationships between the majority of species have remained untested. Here we present the first phylogenetic reconstruction of relationships to encompass most of the currently recognised species diversity in the genus. Three regions of the plastid genome were sequenced in 117 individuals of Fritillaria, representing 92 species (c. 66% of the genus) and in representatives of nine other genera of Liliaceae. Eleven low-copy nuclear gene regions were also screened in selected species for their potential utility. Phylogenetic analysis of a combined plastid dataset using maximum parsimony and Bayesian inference provided support for the monophyly of the majority of currently recognised subgenera. However, subgenus Fritillaria, which is by far the largest of the subgenera and includes the most important species used in traditional Chinese medicine, is found to be polyphyletic. Moreover, several taxa that were represented by multiple individuals show evidence of species non-monophyly. The Japanese endemic subgenus Japonica, which contains the species with the largest recorded genome size for any diploid plant, is resolved as sister to the predominantly Middle Eastern and Central Asian subgenus Rhinopetalum. Whilst relationships between most of the major Fritillaria lineages can now be resolved, our results also highlight the need for data from additional independently evolving loci; an endeavour that may be particularly challenging in light of the huge nuclear genomes found in these plants.