Building the monocot tree of death: Progress and challenges emerging from the macrofossil‐rich Zingiberales

Smith, Selena Y.; Iles, William J. D.; Benedict, John C.; Specht, Chelsea D.

doi:10.1002/ajb2.1123

Cited by 10 publications

(13 citation statements)

References 69 publications

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“…Our study used more taxon sampling and DNA nucleotide to increase the divergence-time estimation accuracy. Among those studies for divergence-time estimation of Musaceae [ 17 , 18 , 20 , 49 ], two fossils ( Spirematospermum chandlerae and Ensete oregonense ) were often used: Ensete oregonense , confirmed to be part of Musaceae [ 51 ] and Spirematospermum chandlerae Friis is the oldest known fossil of the Zingiberales. This study selected one more fossil ( Zingiberopsis attenuate ) and one secondary calibration point compared to other related studies [ 17 , 18 , 20 , 49 ].…”

Section: Discussionmentioning

confidence: 99%

Comparative plastome analysis of Musaceae and new insights into phylogenetic relationships

Rouard

et al. 2022

BMC Genomics

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Background Musaceae is an economically important family consisting of 70-80 species. Elucidation of the interspecific relationships of this family is essential for a more efficient conservation and utilization of genetic resources for banana improvement. However, the scarcity of herbarium specimens and quality molecular markers have limited our understanding of the phylogenetic relationships in wild species of Musaceae. Aiming at improving the phylogenetic resolution of Musaceae, we analyzed a comprehensive set of 49 plastomes for 48 species/subspecies representing all three genera of this family. Results Musaceae plastomes have a relatively well-conserved genomic size and gene content, with a full length ranging from 166,782 bp to 172,514 bp. Variations in the IR borders were found to show phylogenetic signals to a certain extent in Musa. Codon usage bias analysis showed different preferences for the same codon between species and three genera and a common preference for A/T-ending codons. Among the two genes detected under positive selection (dN/dS > 1), ycf2 was indicated under an intensive positive selection. The divergent hotspot analysis allowed the identification of four regions (ndhF-trnL, ndhF, matK-rps16, and accD) as specific DNA barcodes for Musaceae species. Bayesian and maximum likelihood phylogenetic analyses using full plastome resulted in nearly identical tree topologies with highly supported relationships between species. The monospecies genus Musella is sister to Ensete, and the genus Musa was divided into two large clades, which corresponded well to the basic number of n = x = 11 and n = x =10/9/7, respectively. Four subclades were divided within the genus Musa. A dating analysis covering the whole Zingiberales indicated that the divergence of Musaceae family originated in the Palaeocene (59.19 Ma), and the genus Musa diverged into two clades in the Eocene (50.70 Ma) and then started to diversify from the late Oligocene (29.92 Ma) to the late Miocene. Two lineages (Rhodochlamys and Australimusa) radiated recently in the Pliocene /Pleistocene periods. Conclusions The plastome sequences performed well in resolving the phylogenetic relationships of Musaceae and generated new insights into its evolution. Plastome sequences provided valuable resources for population genetics and phylogenetics at lower taxon.

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Section: Discussionmentioning

confidence: 99%

Comparative plastome analysis of Musaceae and new insights into phylogenetic relationships

Rouard

et al. 2022

BMC Genomics

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“…Moreover, the estimated stem age of Zingiberaceae, that is, c. 105 (126-90) Ma, and the crown age of the family, that is, c. 68 (82-65) Ma, were compatible with fossils recorded from the late Cretaceous (Figure 1a). This suggests that using 'Musa' cardiosperma, Spirematospermum chandlerae and Tricostatocarpon silvapinedae to calibrate the stem age of the Zingiberaceae was reasonable (Smith et al, 2018). From the early to late Cretaceous, the climate of northern South America transitioned from arid to humid tropics (extension of tropical climate in Northern Gondwana) (Figure 1b).…”

Section: Discussionmentioning

confidence: 99%

“…Fossil seeds of Ensete and leaves of Zingiberopsis belong to the Musaceae and the Zingiberaceae, respectively. However, although Spirematospermum has been identified as a member of the Musaceae or the Zingiberaceae (Friis, 1988; Fischer et al, 2009), detailed analysis suggested that its origin should be placed in or allied to the Zingiberaceae (Chen & Smith, 2013; Benedict et al, 2015; Smith et al, 2018). Three other fossils were also assigned to the Zingiberaceae (Smith et al, 2018): Striatornata sanantoniensis and Tricostatocarpon silvapinedae found from the Campanian (83.5–72 Ma) in Coahuila, Mexico (Rosa & Cevallos‐Ferriz, 1994), and ‘ Musa ’ cardiosperma , moved from the Musaceae to the Zingiberaceae (Manchester & Kress, 1993), found from the Maastrichtian/Danian boundary (c. 66 Ma) in Deccan, India (Jain, 1963).…”

Section: Methodsmentioning

confidence: 99%

Historical biogeography of the gingers and its implications for shifts in tropical rain forest habitats

Zhao

Kress

et al. 2022

Journal of Biogeography

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Aim The relationships between biome shifts and global environmental changes in temperate zone habitats have been extensively explored; yet, the historical dynamics of taxa found in the tropical rain forest (TRF) remain poorly known. This study aims to reconstruct the relationships between tropical rain forest shifts and global environmental changes through the patterns of historical biogeography of a pantropical family of monocots, the Zingiberaceae. Location Global. Taxon Zingiberaceae. Methods We sampled DNA sequences (nrITS, trnK, trnL‐trnF and psbA‐trnH) from GenBank for 77% of the genera, including 30% of species, in the Zingiberaceae. Global fossil records of the Zingiberaceae were collected from literatures. Rates of speciation, extinction and diversification were estimated based on phylogenetic data and fossil records through methods implemented in BAMM. Ancestral ranges were estimated using single‐tree BioGeoBEARS and multiple‐trees BioGeoBEARS in RASP. Dispersal rate through time and dispersal rate among regions were calculated in R based on the result of ancestral estimation. Results The common ancestor of the Zingiberaceae likely originated in northern Africa during the mid‐Cretaceous, with later dispersal to the Asian tropics. Indo‐Burma, rather than Malesia, was likely a provenance of the common ancestor of Alpinioideae–Zingiberoideae. Several abrupt shifts of evolutionary rates from the Palaeocene were synchronized with sudden global environmental changes. Main conclusions Integrating phylogenetic patterns with fossil records suggests that the Zingiberaceae dispersed to Asia through drift of the Indian Plate from Africa in the late Palaeocene. Formation of island chains, land corridors and warming temperatures facilitated the emigration of the Zingiberaceae to a broad distribution across the tropics. Moreover, dramatic fluctuations of the speciation rate of Zingiberoideae appear to have been synchronized with global climate fluctuations. In general, the evolutionary history of the Zingiberaceae broadens our understanding of the association between TRF shifts in distribution and past global environmental changes, especially the origin of TRF in Southeast Asia.

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“…Four additional studies of extinct species explore flowering plant evolution and phylogeny from fagalean inflorescences (Gandolfo et al., ), ericalean flowers (Crepet et al., ), zingiberalean monocot seeds (Smith et al., ), and Early Cretaceous seeds that are similar to those of basal living angiosperms (Friis et al., ). By comparing key morphological characters of fossil representatives to the pattern of structural features on the fagalean tree, Gandolfo et al.…”

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confidence: 99%

“…The inclusion of fossil seeds in morphological and combined morphological/nucleotide sequence analyses by Smith et al. () helps explain how different topologies from morphological and molecular data sets result from plesiomorphic characters shared by Musaceae, Zingiberaceae, Costaceae, and many zingiberalean fossils. This study emphasizes the pressing need for fossils to be incorporated into phylogenetic analyses, not only to place those fossils on the tree, but also to better understand morphological evolution, to establish character polarities, recognize homoplasy, and identify apparent data conflicts.…”

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confidence: 99%

Tree of death: The role of fossils in resolving the overall pattern of plant phylogeny

Rothwell

Escapa

Tomescu

2018

American J of Botany

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Building the monocot tree of death: Progress and challenges emerging from the macrofossil‐rich Zingiberales

Cited by 10 publications

References 69 publications

Comparative plastome analysis of Musaceae and new insights into phylogenetic relationships

Comparative plastome analysis of Musaceae and new insights into phylogenetic relationships

Historical biogeography of the gingers and its implications for shifts in tropical rain forest habitats

Tree of death: The role of fossils in resolving the overall pattern of plant phylogeny

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