Pairwise comparisons across species are problematic when analyzing functional genomic data

Dunn, Casey W.; Zapata, Felipe; Munro, Catriona; Siebert, Stefan; Hejnol, Andreas

doi:10.1101/107177

Cited by 21 publications

(56 citation statements)

References 47 publications

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“…4a, Table S10). Comparing gene expression across species requires prior knowledge of phylogenetic relationships (Dunn et al, 2017) to account for neutral fluctuations in gene expression levels in different lineages (Rohlfs et al, 2014). Such analyses could not previously be performed with sufficient confidence because (1) branch lengths, as required for downstream analyses, could not be estimated accurately, and (2) the relationship among taxa with newly generated transcriptomes, in particular the placement of the emerging model species Arabis alpina, has not been resolved consistently before our phylogenomic study (Willing et al, 2015).…”

Section: Leaf-form Evolution In Brassicaceaementioning

confidence: 99%

Resolving the backbone of the Brassicaceae phylogeny for investigating trait diversity

et al. 2019

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Summary The Brassicaceae family comprises c. 4000 species including economically important crops and the model plant Arabidopsis thaliana. Despite their importance, the relationships among major lineages in the family remain unresolved, hampering comparative research. Here, we inferred a Brassicaceae phylogeny using newly generated targeted enrichment sequence data of 1827 exons (> 940 000 bases) representing 63 species, as well as sequenced genome data of 16 species, together representing 50 of the 52 currently recognized Brassicaceae tribes. A third of the samples were derived from herbarium material, facilitating broad taxonomic coverage of the family. Six major clades formed successive sister groups to the rest of Brassicaceae. We also recovered strong support for novel relationships among tribes, and resolved the position of 16 taxa previously not assigned to a tribe. The broad utility of these phylogenetic results is illustrated through a comparative investigation of genome‐wide expression signatures that distinguish simple from complex leaves in Brassicaceae. Our study provides an easily extendable dataset for further advances in Brassicaceae systematics and a timely higher‐level phylogenetic framework for a wide range of comparative studies of multiple traits in an intensively investigated group of plants.

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Section: Leaf-form Evolution In Brassicaceaementioning

confidence: 99%

Resolving the backbone of the Brassicaceae phylogeny for investigating trait diversity

et al. 2019

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“…As a decrease in structural [41,37] and functional [23,35,34,4,9,32] similarity with divergence is a widely expected and observed pattern for both paralogs and orthologs, the patterns of evolution in these studies are indeed baffling. Further examination of several of these studies has uncovered problems with the analyses such that there is either no longer support for the ortholog conjecture [15] or that there was no statistical support for the ortholog conjecture in the first place, as in the case of human-mouse comparisons in Ref. [2].…”

Section: Introductionmentioning

confidence: 99%

The Ortholog Conjecture Revisited: the Value of Orthologs and Paralogs in Function Prediction

Stamboulian

Guerrero

Hahn

et al. 2019

Preprint

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The computational prediction of gene function is a key step in making full use of newly sequenced genomes. Function is generally predicted by transferring annotations from homologous genes or proteins for which experimental evidence exists. The "ortholog conjecture" proposes that orthologous genes should be preferred when making such predictions, as they evolve functions more slowly than paralogous genes. Previous research has provided little support for the ortholog conjecture, though the incomplete nature of the data cast doubt on the conclusions. Here we use experimental annotations from over 40,000 proteins, drawn from over 80,000 publications, to revisit the ortholog conjecture in two pairs of species: (i) Homo sapiens and Mus musculus and (ii) Saccharomyces cerevisiae and Schizosaccharomyces pombe. By making a distinction between questions about the evolution of function versus questions about the prediction of function, we find strong evidence against the ortholog conjecture in the context of function prediction, though questions about the evolution of function remain difficult to address. In both pairs of species, we quantify the amount of data that must be ignored if paralogs are discarded, as well as the resulting loss in prediction accuracy. Taken as a whole, our results support the view that the types of homologs used for function transfer are largely irrelevant to the task of function prediction. Aiming to maximize the amount of data used for this task, regardless of whether it comes from orthologs or paralogs, is most likely to lead to higher prediction accuracy.

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“…To evaluate transcriptome similarity between samples, a Spearman correlation coefficient was calculated by using the expression values of orthologous genes, as described by Wang et al 8 . As indicated previously 9,79 , phylogenetic relationships between the species being compared were considered in the transcriptome-based identification of vertebrate-conserved stages. For stage combinations among the six different vertebrate embryos (mouse, chicken, softshell turtle, western clawed flog, zebrafish and medaka), we extracted pairs of species that reflected the phylogenetic scale of interest (i.e., vertebrates) and took their average value as expDist.…”

Section: Preparation and Sequencing Of Atac-seq Librarymentioning

confidence: 99%

Evolutionary transition in accessible chromatin landscapes during vertebrate embryogenesis

Uesaka

Kuratani

Takeda

et al. 2018

Preprint

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The relationship between development and evolution is a central topic in evolutionary biology 1,2 . Recent transcriptome-based studies support the developmental hourglass model, which predicts that the animal embryogenetic program is most strongly conserved at mid-embryonic stages 3-9 . This model does not necessarily contradict the classical hypothesis 10,11 that animal development recapitulates its evolutionary history after the mid-embryonic stages 2,12 . However, to date there is no molecular evidence supporting the hypothesis that geneexpression profiles that are more evolutionarily derived appear sequentially in late development. Here, by estimating activated genomic regions and their evolutionary origins, we show that the recapitulative pattern appears during late embryonic stages. We made a genome-wide assessment of accessible chromatin regions throughout embryogenesis in three vertebrate species (mouse, chicken, and medaka) and determined the phylogenetic range at which these regions were shared. In all three species, sequential activation of putative regulatory regions that were more derived occurred later in embryogenesis, whereas ancestral ones tended to be activated early. Our results clarify the chronologic changes in accessible chromatin landscapes and reveal a phylogenetic hierarchy in the evolutionary origins of putative regulatory regions that parallels developmental stages of activation. This relationship may explain, at least in part, the background for morphological observations of recapitulative events during embryogenesis.

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Pairwise comparisons across species are problematic when analyzing functional genomic data

Cited by 21 publications

References 47 publications

Resolving the backbone of the Brassicaceae phylogeny for investigating trait diversity

Resolving the backbone of the Brassicaceae phylogeny for investigating trait diversity

The Ortholog Conjecture Revisited: the Value of Orthologs and Paralogs in Function Prediction

Evolutionary transition in accessible chromatin landscapes during vertebrate embryogenesis

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