Ancient Polyploidy and Genome Evolution in Palms

Barrett, Craig F.; McKain, Michael R.; Sinn, Brandon T.; Ge, Xue Jun; Zhang, Yu‐Qu; Antonelli, Alexandre; Bacon, Christine D.

doi:10.1093/gbe/evz092

Cited by 31 publications

(31 citation statements)

References 99 publications

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“…They also identify an earlier γ event, which could be the ε WGD, common to angiosperms 49 . The p and τ WGDs were confirmed by a new study covering a wide range of palm transcriptomes 52 . However, that study suggests a 2 n = 30 chromosome common ancestor of palms, which is not supported by chromosome-scale synteny.…”

Section: Resultsmentioning

confidence: 70%

Coconut genome assembly enables evolutionary analysis of palms and highlights signaling pathways involved in salt tolerance

et al. 2021

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Coconut (Cocos nucifera) is the emblematic palm of tropical coastal areas all around the globe. It provides vital resources to millions of farmers. In an effort to better understand its evolutionary history and to develop genomic tools for its improvement, a sequence draft was recently released. Here, we present a dense linkage map (8402 SNPs) aiming to assemble the large genome of coconut (2.42 Gbp, 2n = 32) into 16 pseudomolecules. As a result, 47% of the sequences (representing 77% of the genes) were assigned to 16 linkage groups and ordered. We observed segregation distortion in chromosome Cn15, which is a signature of strong selection among pollen grains, favouring the maternal allele. Comparing our results with the genome of the oil palm Elaeis guineensis allowed us to identify major events in the evolutionary history of palms. We find that coconut underwent a massive transposable element invasion in the last million years, which could be related to the fluctuations of sea level during the glaciations at Pleistocene that would have triggered a population bottleneck. Finally, to better understand the facultative halophyte trait of coconut, we conducted an RNA-seq experiment on leaves to identify key players of signaling pathways involved in salt stress response. Altogether, our findings represent a valuable resource for the coconut breeding community.

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Section: Resultsmentioning

confidence: 70%

Coconut genome assembly enables evolutionary analysis of palms and highlights signaling pathways involved in salt tolerance

et al. 2021

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“…The minimum chromosome number allowed in the analyses was set to 2, whereas the maximum number was set to 5 units higher than the highest chromosome number found in the empirical data. We removed all counts n > 43 from the analysis, because for many lineages the sampling was inadequate to reconstruct such a drastic change in chromosome number 38–39 and because of computation limitations 23 . The branch lengths were scaled according to the software author’s instructions.…”

Section: Methodsmentioning

confidence: 99%

A deep dive into the ancestral chromosome number and genome size of flowering plants

Carta

Bedini

Peruzzi

2020

Preprint

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7Chromosome rearrangements are a well-known evolutionary feature in eukaryotic organisms 1 , 8 especially plants. The remarkable diversity of flowering plants (angiosperms) has been 9 attributed, in part, to the tremendous variation in their chromosome number 2 . This variation has 10 stimulated a blossoming number of speculations about the ancestral chromosome number of 11 angiosperms 2-7 , but estimates so far remain equivocal and relied on algebraic approaches lacking 12 an explicit phylogenetic framework. Here we used a probabilistic approach to model haploid 13 chromosome number (n) changes 8 along a phylogeny embracing more than 10 thousands taxa, 14 to reconstruct the ancestral chromosome number of the common ancestor of extant angiosperms 15 and the most recent common ancestor for single angiosperm families. 16Bayesian inference revealed an ancestral haploid chromosome number for angiosperms n = 7, 17 reinforcing previous hypotheses 2-7 that suggested a low ancestral basic number. Inferred n for 18 single families, more than half of which are provided here for the first time, are mostly 19 congruent with previous evaluations. Chromosome fusion (loss) and duplication (polyploidy) 20 are the predominant transition types inferred along the phylogenetic tree, emphasising the 21 importance of both dysploidy 6,9,10 and genome duplication 2,7,11-13 in chromosome number 22 evolution. Significantly, while dysploidy is equally distributed early and late across the whole 23 phylogeny, polyploidy is detected mainly towards the tips of the tree. Therefore, little evidence 24 exists for a link between ancestral chromosome numbers and putative ancient polyploidization 25 events 14 , suggesting that further insights are needed to elucidate the organization of genome 26 packaging into chromosomes. 27 28 Each eukaryotic organism has a characteristic chromosome complement, its karyotype, which 29 represents the highest level of structural and functional organization of the nuclear genome 15 . 30 Karyotype constancy ensures the transfer of the same genetic material to the next generation, 31 while karyotype variation provides genetic support to ecological differentiation and 32 adaptation 2,15 . Cytogenetic studies have shown that the tremendous inter-and intra-taxonomic 33 variation of chromosome number documented in flowering plants 2,5,16 is mostly driven by two 34 major mechanisms: a) increases through polyploidy (which may entail a Whole Genome 35 Duplication [WGD] or an increase by half of the genome, demi-duplication 8 ); b) decreases or 36 increases through structural chromosomal rearrangements like chromosome fusion, i.e. 37descending dysploidy, and chromosome fission, i.e. ascending dysploidy. 38Polyploidy is a common and ongoing phenomenon, especially in plants 13 , that has played an 39 important role in many lineages, with evidence of several rounds of both ancient and recent 40 polyploidization 11,17,18 , albeit its distribution in time remains contested 14 . Indeed, although the 41 crucial role of polyploidy i...

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“…Genome assembly of Phalaenopsis equestris (the horse phalaenopsis) (Cai et al, 2015) provided novel opportunities for evolutionary and functional studies of Orchidaceae. Genome assembly was used for the functional studies of transcription factor families (Lin et al, 2016; Valoroso et al, 2019), somatic embryogenesis (Chen et al, 2019), retrotransposon insertions (Hsu et al, 2019), as well as for evolutionary studies of ancient polyploidy (Barrett et al, 2019). However, transcriptome resources of P. equestris remain limited even though the de novo transcriptome assembly was performed based on RNA sequencing of 11 organs (Niu et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Transcriptome atlas ofPhalaenopsis equestris

et al. 2020

Preprint

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The vast diversity of Orchidaceae together with sophisticated adaptations to pollinators and other unique features make this family an attractive model for evolutionary and functional studies. The sequenced genome of Phalaenopsis equestris facilitates Orchidaceae research. Here we present an RNA-seq based transcriptome map of P. equestris which covers 19 organs of the plant including leaves, roots, floral organs and shoot apical meristem. We demonstrated the high quality of the data and showed the similarity of P. equestris transcriptome map with gene expression atlases of other plants. The transcriptome map can be easily accessed through our database Transcriptome Variation Analysis (TraVA) visualizing gene expression profiles. As an example of the application we analyzed the expression of Phalaenopsis "orphan" genes - the ones that do not have recognizable similarity with genes of other plants. We found that about a half of them are not expressed; the ones that are expressed have a predominant expression pattern in reproductive structures.

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Ancient Polyploidy and Genome Evolution in Palms

Cited by 31 publications

References 99 publications

Coconut genome assembly enables evolutionary analysis of palms and highlights signaling pathways involved in salt tolerance

Coconut genome assembly enables evolutionary analysis of palms and highlights signaling pathways involved in salt tolerance

A deep dive into the ancestral chromosome number and genome size of flowering plants

Transcriptome atlas ofPhalaenopsis equestris

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