Major clades and a revised classification of <i>Magnolia</i> and Magnoliaceae based on whole plastid genome sequences via genome skimming

YU-BING, YU-BING; Liu, Bin‐Bin; Nie, Ze‐Long; Chen, Hongfeng; Chen, Faju; Figlar, Richard B.; Wen, Jun

doi:10.1111/jse.12588

Cited by 84 publications

(110 citation statements)

References 72 publications

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“…Increasingly, robust phylogenies based on extensive or complete sampling of species derived from analyses of genomic data are available to serve as the basis for classification. In this issue, Wang et al (2020b) present a revised classification of Magnolia L. and the Magnoliaceae, based on results from phylogenomic analyses of plastid genome sequences from genome skimming with broad taxon sampling. Similarly, Ye et al (2020) conducted a phylogenetic study of Diapensiaceae using chloroplast genome data and a broad sampling of Diapensia L. to address the status of several species.…”

Section: Editorialmentioning

confidence: 99%

In memory of Professor Tang Yan‐Cheng: New perspectives in systematic and evolutionary biology

Xiang

Chen

Song

et al. 2020

J of Sytematics Evolution

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Section: Editorialmentioning

confidence: 99%

In memory of Professor Tang Yan‐Cheng: New perspectives in systematic and evolutionary biology

Xiang

Chen

Song

et al. 2020

J of Sytematics Evolution

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“…Genome skimming has often been used to target the high-copy fractions of genomes including plastomes, mitochondrial genomes (mitogenomes), and nuclear ribosomal DNA (nrDNA) repeats (Straub et al, 2012;Dodsworth, 2015;Zhang et al, 2015;Thode et al, 2020), and these datasets have been widely used for inferring phylogenies in many recent studies. For example, the chloroplast genome has been widely utilized for inferring the phylogenetic relationships at various levels (Bock et al, 2014;Zhang et al, 2015;Valcárcel & Wen, 2019;Zhang et al, 2019;Wang et al, 2020), clarifying generic and species delimitations (Wen et al, 2018a;Liu et al, 2019;, as well as acting as an ultra-barcode in plants (Kane et al, 2012;Hollingsworth et al, 2016). The uniparental (mostly maternal, rarely paternal) inheritance and non-recombinant nature of the plastomes make them the ideal marker for tracking the maternal (rarely paternal) history, providing useful evidence to untangle hybridization events in plants (Rieseberg & Soltis, 1991;Sun et al, 2015;Folk et al, 2017;Vargas et al, 2017;Morales-Briones et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Capturing single-copy nuclear genes, organellar genomes, and nuclear ribosomal DNA from deep genome skimming data for plant phylogenetics: A case study in Vitaceae

Liu

Ren

et al. 2021

Preprint

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With the decreasing cost and availability of many newly developed bioinformatics pipelines, next-generation sequencing (NGS) has revolutionized plant systematics in recent years. Genome skimming has been widely used to obtain high-copy fractions of the genomes, including plastomes, mitochondrial DNA (mtDNA), and nuclear ribosomal DNA (nrDNA). In this study, through simulations, we evaluated optimal (minimum) sequencing depth and performance for recovering single-copy nuclear genes (SCNs) from genome skimming data, by subsampling genome resequencing data and generating 10 datasets with different sequencing coverage in silico. We tested the performance of the four datasets (plastome, nrDNA, mtDNA, and SCNs) obtained from genome skimming based on phylogenetic analyses of the Vitis clade at the genus-level and Vitaceae at the family-level, respectively. Our results showed that optimal minimum sequencing depth for high-quality SCNs assembly via genome skimming was about 10x coverage. Without the steps of synthesizing baits and enrichment experiments, we showcase that deep genome skimming (DGS) is effective for capturing large datasets of SCNs, in addition to plastomes, mtDNA, and entire nrDNA repeats, and may serve as an economical alternative to the widely used target enrichment Hyb-Seq approach.

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“…The family Magnoliaceae Juss. [3] belongs to one of the basal clades in the angiosperms, it consists of 350 species, two genera, Liriodendron L. [4] and Magnolia L. [4] and 15 sections [5]. It is disjunct and bicontinental; in the America and SE Asia, from near sea level to 3400 m [6].…”

Section: Introductionmentioning

confidence: 99%

How to Save Endangered Magnolias? From Population Biology to Conservation Action: The Case of Allopatric Radiation in Western Mexico

Vázquez-García¹,

Muñiz-Castro²,

Dahua-Machoa³

et al. 2021

Endangered Plants

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Numerous Neotropical Magnolia species are endangered and red-listed by the IUCN. Here we highlight major results from over a decade of research on endangered magnolias in western Mexico. Particularly, we compare three species of Magnolia (M. pugana, M. pacifica and M. vallartensis) along a large-scale continentality and moisture gradients, in terms of a) their morphological adaptations, b) genetic structure, diversity, and differentiation, c) reproductive phenology, and d) floral scents and their floral visitors. Fieldwork along this gradient unveiled two new species of Magnolia sect. Magnolia; M. granbarrancae and M. talpana. We found that most continental populations have a higher extinction risk than those with greater maritime influence, due to their lower genetic diversity, and greater fragmentation, isolation, and water stress. Also, these populations are more vulnerable to the environmental conditions predicted with the global warming climate scenarios. We share fieldwork experience and advise on pre-germination treatments and seed dormancy. We propose an ex-situ and in-situ conservation strategy, identify new challenges, and suggest future directions of collaborative work as a global Magnolia conservation consortium.

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Major clades and a revised classification of Magnolia and Magnoliaceae based on whole plastid genome sequences via genome skimming

Cited by 84 publications

References 72 publications

In memory of Professor Tang Yan‐Cheng: New perspectives in systematic and evolutionary biology

In memory of Professor Tang Yan‐Cheng: New perspectives in systematic and evolutionary biology

Capturing single-copy nuclear genes, organellar genomes, and nuclear ribosomal DNA from deep genome skimming data for plant phylogenetics: A case study in Vitaceae

How to Save Endangered Magnolias? From Population Biology to Conservation Action: The Case of Allopatric Radiation in Western Mexico

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