Early diversification and karyotype evolution of flowering plants

Sun, Pengchuan; Yang, Yongzhi; Liu, Liang; Xi, Zhenxiang; Lin, Hao; Feng, Landi; Ma, Junsheng; Hu, Hongyin; Bi, Guoan; Jiao, Beibei; Wang, Shang; Yang, Jing; Mu, Wenjie; Zhu, Mingjia; Wang, Xiyin; Wang, Zhenyue; Davis, Charles C.; Liu, Jianquan

doi:10.21203/rs.3.rs-1410884/v1

Cited by 4 publications

(9 citation statements)

References 33 publications

(102 reference statements)

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“…Therefore, the presence of paralogous genes arising from WGD might also make it difficult to accurately extract true nuclear “orthologous genes” for phylogenetic reconstruction (Xiong et al, 2022). The assumed nuclear “orthologous” genes from different species with independent WGD events might have arisen from the random retention of one copy from the duplicated pair, making them “paralogous” rather than “orthologous.” One possible solution to this issue is to avoid using traditional methods to extract nuclear “orthologous” genes and instead to identify all “colinear and paralogous” genes from chromosome‐level high‐quality de novo genomes for phylogenetic analysis (Sun et al, 2022; Xiong et al, 2022). In addition, examining changes in genomic structure or karyotypic evolution may be useful for independently examining the phylogenetic relationships of disputed lineages in angiosperms (Sun et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

“…One possible solution to this issue is to avoid using traditional methods to extract nuclear "orthologous" genes and instead to identify all "colinear and paralogous" genes from chromosome-level high-quality de novo genomes for phylogenetic analysis (Sun et al, 2022;Xiong et al, 2022). In addition, examining changes in genomic structure or karyotypic evolution may be useful for independently examining the phylogenetic relationships of disputed lineages in angiosperms (Sun et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

“…Polyploidizations or whole‐genome duplications (WGDs) are very common in plants (Jiao et al, 2011). It is likely that the species selected to represent the same unit during different analyses may have different polyploidization histories, which may lead to the misidentification of orthologs due to recent WGD(s) (Sun et al, 2022). Horizontal gene transfer, which is likely to occur for both plastomes and mitochondrial genomes (Albert et al, 2013), may also lead to phylogenetic inconsistencies between phylogenies based on different genomes.…”

Section: Introductionmentioning

confidence: 99%

“…Phylogenetic reconstructions of these different genome‐scale datasets and further topological comparisons may help to prevent the discrepancies arising from the selection of different species. In addition, the use of orthologous or single‐copy nuclear sequences from de novo genomes is more accurate compared with transcriptome data and/or TSCD because duplicated colinear genes could easily be identified in well assembled genomes (Sun et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

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Genome‐scale angiosperm phylogenies based on nuclear, plastome, and mitochondrial datasets

Sun

Yang

et al. 2023

JIPB

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Angiosperms dominate the Earth's ecosystems and provide most of the basic necessities for human life. The major angiosperm clades comprise 64 orders, as recognized by the APG IV classification. However, the phylogenetic relationships of angiosperms remain unclear, as phylogenetic trees with different topologies have been reconstructed depending on the sequence datasets utilized, from targeted genes to transcriptomes. Here, we used currently available de novo genome data to reconstruct the phylogenies of 366 angiosperm species from 241 genera belonging to 97 families across 43 of the 64 orders based on orthologous genes from the nuclear, plastid, and mitochondrial genomes of the same species with compatible datasets. The phylogenetic relationships were largely consistent with previously constructed phylogenies based on sequence variations in each genome type. However, there were major inconsistencies in the phylogenetic relationships of the five Mesangiospermae lineages when different genomes were examined. We discuss ways to address these inconsistencies, which could ultimately lead to the reconstruction of a comprehensive angiosperm tree of life. The angiosperm phylogenies presented here provide a basic framework for further updates and comparisons. These phylogenies can also be used as guides to examine the evolutionary trajectories among the three genome types during lineage radiation.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Genome‐scale angiosperm phylogenies based on nuclear, plastome, and mitochondrial datasets

Sun

Yang

et al. 2023

JIPB

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“…Subgenome-aware phylogeny, a phylogenetic methodology based on a comprehensive gene set derived from the subgenomes of a polyploid, can offer a more robust and insightful framework than phylogenetic approaches at the gene or syntenic block level for deciphering the origin and evolutionary trajectories of polyploids. This subgenome-aware phylogenetic approach has been used to probe the evolutionary history, including diversification and polyploidization processes, not only in early angiosperms [ 10 , 11 ] but also in recently formed allopolyploids and interspecific hybrids, including those found in cereals [ 12 ], trees [ 13 ], fruits [ 14 ], vegetables [ 15 ], herbs [ 16 ] and fish [ 17 ]. A vital step in these studies is the phasing of a polyploid’s subgenomes, which involves sorting the subgenomes according to their parental origin with the highest possible precision.…”

Section: Introductionmentioning

confidence: 99%

Subgenome phasing for complex allopolyploidy: case-based benchmarking and recommendations

Zhang,

Shang,

Jia

et al. 2023

Briefings in Bioinformatics

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Accurate subgenome phasing is crucial for understanding the origin, evolution and adaptive potential of polyploid genomes. SubPhaser and WGDI software are two common methodologies for subgenome phasing in allopolyploids, particularly in scenarios lacking known diploid progenitors. Triggered by a recent debate over the subgenomic origins of the cultivated octoploid strawberry, we examined four well-documented complex allopolyploidy cases as benchmarks, to evaluate and compare the accuracy of the two software. Our analysis demonstrates that the subgenomic structure phased by both software is in line with prior research, effectively tracing complex allopolyploid evolutionary trajectories despite the limitations of each software. Furthermore, using these validated methodologies, we revisited the controversial issue regarding the progenitors of the octoploid strawberry. The results of both methodologies reaffirm Fragaria vesca and Fragaria iinumae as progenitors of the octoploid strawberry. Finally, we propose recommendations for enhancing the accuracy of subgenome phasing in future studies, recognizing the potential of integrated tools for advanced complex allopolyploidy research and offering a new roadmap for robust subgenome-based phylogenetic analysis.

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Genome evolution of the ancient hexaploid Platanus × acerifolia (London planetree)

Yan,

Shi,

Sun

et al. 2024

Proc. Natl. Acad. Sci. U.S.A.

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Whole-genome duplication (WGD; i.e., polyploidy) and chromosomal rearrangement (i.e., genome shuffling) significantly influence genome structure and organization. Many polyploids show extensive genome shuffling relative to their pre-WGD ancestors. No reference genome is currently available for Platanaceae (Proteales), one of the sister groups to the core eudicots. Moreover, Platanus × acerifolia (London planetree; Platanaceae) is a widely used street tree. Given the pivotal phylogenetic position of Platanus and its 2-y flowering transition, understanding its flowering-time regulatory mechanism has significant evolutionary implications; however, the impact of Platanus genome evolution on flowering-time genes remains unknown. Here, we assembled a high-quality, chromosome-level reference genome for P. × acerifolia using a phylogeny-based subgenome phasing method. Comparative genomic analyses revealed that P . × acerifolia (2 n = 42) is an ancient hexaploid with three subgenomes resulting from two sequential WGD events; Platanus does not seem to share any WGD with other Proteales or with core eudicots. Each P . × acerifolia subgenome is highly similar in structure and content to the reconstructed pre-WGD ancestral eudicot genome without chromosomal rearrangements. The P . × acerifolia genome exhibits karyotypic stasis and gene sub-/neo-functionalization and lacks subgenome dominance. The copy number of flowering-time genes in P. × acerifolia has undergone an expansion compared to other noncore eudicots, mainly via the WGD events. Sub-/neo-functionalization of duplicated genes provided the genetic basis underlying the unique flowering-time regulation in P. × acerifolia . The P . × acerifolia reference genome will greatly expand understanding of the evolution of genome organization, genetic diversity, and flowering-time regulation in angiosperms.

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Early diversification and karyotype evolution of flowering plants

Cited by 4 publications

References 33 publications

Genome‐scale angiosperm phylogenies based on nuclear, plastome, and mitochondrial datasets

Genome‐scale angiosperm phylogenies based on nuclear, plastome, and mitochondrial datasets

Subgenome phasing for complex allopolyploidy: case-based benchmarking and recommendations

Genome evolution of the ancient hexaploid Platanus × acerifolia (London planetree)

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