Reply to: Revisiting the origin of octoploid strawberry

replying to A. Liston et al. Nature Genetics https://doi.org/10.1038/s41588-019-0543-3 (2019)

The origin of octoploid strawberry has been the focus of several phylogenetic studies over the past decade (for example, refs. ^1,2,3). Our previous study, using the octoploid genome and transcriptomes of every extant diploid Fragaria species, provided support for four species (Fragaria vesca, Fragaria iinumae, Fragaria viridis and Fragaria nipponica) as the closest extant relatives of the diploids that contributed to the origin of octoploid strawberry⁴. In a response paper⁵, Liston et al. stated “that only two extand diploids were progenitors” with one subgenome being contributed by F. vesca and three by F. iinumae–like ancestors. Our reanalysis of the transcriptome data and comparative genomic analyses of a chromosome-scale F. iinumae genome support our previous model for the origin of octoploid strawberry⁴.

Liston et al.⁵ raised a concern regarding one of the steps in the phylogenetic analysis of the subgenome tree-searching algorithm (PhyDS) tool we developed to identify extant relatives of diploid progenitors of allopolyploids. Specifically, they argue that we may have incorrectly identified F. viridis and F. nipponica as extant relatives because in-paralogs were excluded from our previous phylogenetic analysis⁴. Our reanalysis of the data using PhyDS, now including in-paralogs, yielded results consistent with those presented in our previous study (Fig. 1; Supplementary Information and Supplementary Dataset 1). Furthermore, their alternative model for the origin of octoploid strawberry (1× F. vesca–like and 3× F. iinumae–like subgenomes) is not supported by comparative genomic analyses of a new chromosome-scale F. iinumae genome (Fig. 2).

Fig. 1: Phylogenetic analyses.

a, Number of genes from species identified as being sister to a homoeolog from the octoploid genome, by using PhyDS with bootstrap support value (BSV) cutoffs. Based on previous results⁴. b, Reanalysis of the data, including in-paralogs and BSV₅₀ cutoff, identified the same progenitor species. The prevalence and biased patterns of homoeologous exchanges between subgenomes resulted in the dominant F. vesca subgenome replacing a greater number of corresponding regions in each of the recessive subgenomes⁴. Thus, a greater number of genes from the dominant F. vesca subgenome were identified, with the F. iinumae–like subgenome being second.

Fig. 2: Divergence of K_s rates among subgenomes.

a, Synonymous substitution divergence for all syntenic genes between the F. iinumae and Fragaria × ananassa genomes⁴. The median K_s divergence values for the seven chromosomes previously assigned to each progenitor species are plotted. The F. iinumae and F. vesca subgenomes exhibit the lowest and highest K_s divergence, respectively. b–d, K_s analysis of F. iinumae (b), F. viridis (c) and F. nipponica (d) transcriptomes against the phylogenetically supported homoeolog in the octoploid genome. The K_s distributions of F. viridis and F. nipponica transcriptomes are both unique and distinct from that of F. iinumae.

Phylogenetic analysis of the subgenome tree-searching algorithm searched a set of gene trees to identify sequences most closely related to a set of user-provided paralogs (or homoeologs in polyploids). Homoeologs are orthologous genes that were brought back into the same nucleus by allopolyploidization⁶. For our analyses, we used syntenic (that is, positionally conserved) homoeologs that were present on all subgenomes in octoploid strawberry. Gene trees were estimated using RAxML⁷ based on orthologs identified using established orthogrouping approaches⁸ applied to de novo assembled transcriptomes for each diploid Fragaria species⁴. PhyDS performs a relatively simple and straightforward analysis of gene trees. First, it identifies the user-provided paralog present in a gene tree and then moves to the direct ancestral node of the paralog. Second, PhyDS then returns to the user the direct descendants (that is, sequence identities including the paralog) of that ancestral node with its bootstrap support value (Fig. 1).

We have two major concerns regarding the methods used in refs. ^2,5. First, phylogenetic analyses aimed at estimation of species relationships are reliant first on correct identification of orthologs⁹. These authors used a sequence similarity-based approach to identify putative orthologs that has relatively high error rates¹⁰. Furthermore, pangenome studies have shown that up to one-half of gene content exhibits presence–absence variation at the species level in plants¹¹. In other words, many genes are individual- or population-specific. Thus, many of the putative ortholog predictions in their studies may be inaccurate. Second, Liston et al.⁵ performed analyses of 100-kb windows across each of the seven base chromosomes. This could be problematic because chromosomal regions from one parental species can be replaced with chromosomal regions from the other parental species during meiosis in polyploids (referred to as homoeologous exchanges¹²). Homoeologous exchanges can range in size from large megabase-sized regions to single genes (see a recent review on its impact on subgenome assignment in ref. ¹³). We identifed extensive homoeologous exchanges throughout the octoploid strawberry genome⁴. Thus, the 100-kb windows Liston et al. used consist of genes with different evolutionary histories reflecting each of the different progenitor species. This could result in inaccurate estimates of species relationships.

Here we present a chromosome-scale genome of F. iinumae with a scaffold minimum scaffold length needed to cover 50% of the genome of 33.98 Mb and 23,665 protein-coding genes (see Supplementary Information). This genome was used to calculate the synonymous substitution (K_s) divergence between F. iinumae to each of the four subgenomes (Fig. 2a). This revealed that only one of the subgenomes of octoploid strawberry is F. iinumae–like, which does not support the model presented by Liston et al.⁵ that the origin of octoploid strawberry involved three F. iinumae–like and one F. vesca–like progenitor species. Instead, these results are consistent with our phylogenetic estimates supporting more than two diploid progenitors (Fig. 2b–d). The F. viridis (Fig. 2c) and F. nipponica (Fig. 2d) subgenomes are not F. iinumae–like.

Our new phylogenetic analyses support four distinct progenitor species, which is consistent with our previous results⁴ and that of other groups³. The conflicting results obtained by Liston et al.⁵ are probably due to differences in methodology. As pointed out above, establishing gene orthology is crucial for molecular phylogenetics. Our pipeline started by identifying high-confidence syntenic 1:1 homoeologs present on each of the subgenomes. This step alone filtered out 82.1% of genes from the octoploid strawberry genome⁴. The number of genes analyzed in our study was further reduced due to absence across transcriptome data, stringent orthogroup filtering and bootstrap value filtering. In short, more data are not always better if one introduces ‘phylogenetic noise’. It is unclear to us how Liston et al.⁵ obtained high unique mapping rates (~89% alignment) across the F. vesca genome, which consists of ~31% transposable elements and hundreds of duplicate genes. Furthermore, many genes are species-specific based on previous pangenome studies.

As pointed out by Liston et al.⁵, incomplete lineage sorting can impact phylogenetic inferences. However, that is far more likely to impact within-species than between-species estimates. This is exactly what was observed in our study. Other F. vesca subspecies were identified as contributors but were present at notably lower levels than F. viridis and F. nipponica (Fig. 1a). These patterns provide further support for F. viridis and F. nipponica as extant relatives of the progenitors that contributed to the origin of the intermediate hexaploid ancestor. Lastly, we did state that F. moschata may be an extant relative of the intermediate hexaploid ancestor. Given the high frequency of polyploid formation in Fragaria¹⁴ and birth–death dynamics of polyploids¹⁵, we agree it is possible that the hexaploid ancestor may be extinct. This remains to be properly evaluated using robust phylogenetic approaches and datasets.

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