Polyploid plants have faster rates of multivariate niche differentiation than their diploid relatives

Baniaga, Anthony E.; Marx, Hannah E.; Arrigo, Nils; Barker, Michael S.

doi:10.1111/ele.13402

Cited by 129 publications

(112 citation statements)

References 156 publications

(174 reference statements)

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“…Presently, our results provide a testable hypothesis to explain the observed correlation of polyploidy and crop domestication 10 .More broadly, our results suggest that paleopolyploidy may leave behind a legacy of elevated genetic diversity across the duplicated remnants of diploidized genomes. Although most models and studies of polyploid evolution compare diploids and polyploids11,12,14,16,17,19,[70][71][72] , our comparison of paleologs and non-paleologs within a diploidized paleopolyploid uncovered evidence for similar dynamics ongoing within plant genomes even millions of years after whole genome duplication. The extensive genome duplication history of plants may result in genomes with different levels of diversity based on the mechanisms of gene origin.…”

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confidence: 88%

“…Analyses in yeast have shown that polyploid lineages not only have higher genetic diversity but also adapt to new environments faster than their lower ploidal level relatives 16 . Similarly, the niches of polyploid plants evolve faster than their diploid relatives 17 . These features may collectively give polyploids unique advantages over diploids during domestication and the global spread of crops that occurred with human population expansion.…”

Section: Introductionmentioning

confidence: 99%

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Genes derived from ancient polyploidy have higher genetic diversity and are associated with domestication inBrassica rapa

Hall

et al. 2019

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Many crops are polyploid or have a polyploid ancestry. Recent phylogenetic analyses have found that polyploidy often preceded the domestication of crop plants. One explanation for this observation is that increased genetic diversity following polyploidy may have been important during the strong artificial selection that occurs during domestication. To test the connection between domestication and polyploidy, we identified and examined candidate genes associated with the domestication of the diverse crops of Brassica rapa . Like all "diploid" flowering plants, B. rapa has a diploidized paleopolyploid genome and experienced many rounds of whole genome duplication (WGD). We analyzed transcriptome data of more than hundred cultivated B. rapa accessions. Using a combination of approaches, we identified more than 3,000 candidate genes associated with the domestication of four major B. rapa crops. Consistent with our expectation, we found that the candidate genes were significantly enriched with genes derived from the Brassiceae mesohexaploidy. We also observed that paleologs contained significantly more genetic diversity than non-paleologs, suggesting that elevated genetic variation may explain why paleologs are enriched among domestication candidate genes. Our analyses demonstrate the key role of polyploidy in the domestication of B. rapa and provide support for its importance in the success of modern agriculture.

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confidence: 88%

Section: Introductionmentioning

confidence: 99%

Genes derived from ancient polyploidy have higher genetic diversity and are associated with domestication inBrassica rapa

Hall

et al. 2019

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“…Despite recent work using ecological modelling across species to address the success of polyploids (e.g. Martin & Husband 2009;Glennon et al 2014;Marchant et al 2016;Baniaga et al 2019), the evolution of their ecological niches following the combination of diploids remains elusive. To account for the impact of hybridisation between differentially adapted taxa, Parisod & Broennimann (2016) suggested to not only rely on adequate phylogenies but to go beyond ambiguous pairwise comparisons by testing the null hypothesis that allopolyploids represent the additivity of their diploid progenitors.…”

Section: Introductionmentioning

confidence: 99%

Eco‐genetic additivity of diploids in allopolyploid wild wheats

et al. 2020

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Underpinnings of the distribution of allopolyploid species (hybrids with duplicated genome) along spatial and ecological gradients are elusive. As allopolyploid speciation combines the range of genetic and ecological characteristics of divergent diploids, allopolyploids initially show their additivity and are predicted to evolve differentiated ecological niches to establish in face of their competition. Here, we use four diploid wild wheats that differentially combined into four independent allopolyploid species to test for such additivity and assess the impact of ecological constraints on species ranges. Divergent genetic variation from diploids being fixed in heterozygote allopolyploids supports their genetic additivity. Spatial integration of comparative phylogeography and modelling of climatic niches supports ecological additivity of locally adapted diploid progenitors into allopolyploid species which subsequently colonised wide ranges. Allopolyploids fill suitable range to a larger extent than diploids and conservative evolution following the combination of divergent species appears to support their expansion under environmental changes.

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“…Many questions in ecology and evolutionary biology increasingly require combining data from these fields at large scales. In particular, integrated, large-scale analyses of multispecies ecological and phylogenetic data sets have become critical to understanding plant distributions and responses to climate change (Zanne et al, 2014;Swenson and Jones, 2017;Maitner et al, 2018;Enquist et al, 2019;Gallagher et al, 2019;McFadden et al, 2019;Rice et al, 2019;Baniaga et al, 2020;Román-Palacios and Wiens, 2020) . Recognizing this need, NSF recently launched the National Ecological Observatory Network (NEON) to generate large-scale data on species occurrence, phenology, climate, and more, for ecological communities across the United States (Collinge, 2018;Knapp and Collins, 2019) .…”

Section: Introductionmentioning

confidence: 99%

Progress Towards Plant Community Transcriptomics: Pilot RNA-Seq Data from 24 Species of Vascular Plants at Harvard Forest

Marx

Jorgensen

Wisely

et al. 2020

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Premise of the study: Large scale projects such as NEON are collecting ecological data on entire biomes to track and understand plant responses to climate change. NEON provides an opportunity for researchers to launch community transcriptomic projects that ask integrative questions in ecology and evolution. We conducted a pilot study to investigate the challenges of collecting RNA-seq data from phylogenetically diverse NEON plant communities, including species with diploid and polyploid genomes.• Methods: We used Illumina NextSeq to generate >20 Gb of RNA-seq for each of 24 vascular plant species representing 12 genera and 9 families at the Harvard Forest NEON site. Each species was sampled twice, in July and August 2016. We used Transrate, BUSCO, and GO analyses to assess transcriptome quality and content. • Results: We obtained nearly 650 Gb of RNA-seq data that assembled into more than 755,000 translated protein sequences across the 24 species. We observed only modest differences in assembly quality scores across a range of k-mer values. On average, transcriptomes contained hits to >70% of loci in the BUSCO

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Polyploid plants have faster rates of multivariate niche differentiation than their diploid relatives

Cited by 129 publications

References 156 publications

Genes derived from ancient polyploidy have higher genetic diversity and are associated with domestication inBrassica rapa

Genes derived from ancient polyploidy have higher genetic diversity and are associated with domestication inBrassica rapa

Eco‐genetic additivity of diploids in allopolyploid wild wheats

Progress Towards Plant Community Transcriptomics: Pilot RNA-Seq Data from 24 Species of Vascular Plants at Harvard Forest

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