Efficient Identification of the Forest Tree Species in Aceraceae Using DNA Barcodes

Han, Yuwei; Duan, Dong; Ma, Xiongfeng; Jia, Yafei; Liu, Zhan‐Lin; Zhao, Guifang; Li, Zhong-Hu

doi:10.3389/fpls.2016.01707

Cited by 30 publications

(24 citation statements)

References 50 publications

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“…The maximum number included in a single dataset is six, but the resulting trees failed to provide adequate resolution and support for many major clades (Renner et al, 2007;Renner et al, 2008). Two additional loci, matK and trnS-trnG, were explored along with rbcL as barcodes to distinguish among 85 Acer species, but they also showed low discrimination power even when used in combination (Han et al, 2016). Only one of these commonly used markers, psbA-trnH, was identified in this study among the most variable in the genus.…”

Section: Plastome Composition and Variable Regionsmentioning

confidence: 99%

Plastome comparative genomics in maples resolves the infrageneric backbone relationships

Areces-Berazain

Wang

Hinsinger

et al. 2020

PeerJ

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Maples (Acer) are among the most diverse and ecologically important tree genera of the north-temperate forests. They include species highly valued as ornamentals and as a source of timber and sugar products. Previous phylogenetic studies employing plastid markers have not provided sufficient resolution, particularly at deeper nodes, leaving the backbone of the maple plastid tree essentially unresolved. We provide the plastid genome sequences of 16 species of maples spanning the sectional diversity of the genus and explore the utility of these sequences as a source of information for genetic and phylogenetic studies in this group. We analyzed the distribution of different types of repeated sequences and the pattern of codon usage, and identified variable regions across the plastome. Maximum likelihood and Bayesian analyses using two partitioning strategies were performed with these and previously published sequences. The plastomes ranged in size from 155,212 to 157,023 bp and had structure and gene content except for Acer palmatum (sect. Palmata), which had longer inverted repeats and an additional copy of the rps19 gene. Two genes, rps2 and rpl22, were found to be truncated at different positions and might be non-functional in several species. Most dispersed repeats, SSRs, and overall variation were detected in the non-coding sequences of the LSC and SSC regions. Fifteen loci, most of which have not been used before in the genus, were identified as the most variable and potentially useful as molecular markers for barcoding and genetic studies. Both ML and Bayesian analyses produced similar results irrespective of the partitioning strategy used. The plastome-based tree largely supported the topology inferred in previous studies using cp markers while providing resolution to the backbone relationships but was highly incongruous with a recently published nuclear tree presenting an opportunity for further research to investigate the causes of discordance, and particularly the role of hybridization in the diversification of the genus. Plastome sequences are valuable tools to resolve deep-level relationships within Acer. The variable loci and SSRs identified in this study will facilitate the development of markers for ecological and evolutionary studies in the genus. This study underscores the potential of plastid genome sequences to improve our understanding of the evolution of maples.

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Section: Plastome Composition and Variable Regionsmentioning

confidence: 99%

Plastome comparative genomics in maples resolves the infrageneric backbone relationships

Areces-Berazain

Wang

Hinsinger

et al. 2020

PeerJ

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“…It is known that Salix may have undergone repeated plastid capture events, widespread hybridization and dispersal and trans-species selective sweeps that resulted in a general lack of haplotype variation for a number of standard coding and non-coding barcode regions of the chloroplast genome (Percy et al, 2014). Similarly, the low species resolution of the four-species genera Acer and Sorbus here may also result from the hybridization (Han et al, 2016;Li, Ohi-Toma et al 2017). Rhododendron may have undergone recent radiations and hybridization events in the mountain regions of Southwest China .…”

Section: Life Form and Species Resolutionmentioning

confidence: 99%

DNA barcoding herbaceous and woody plant species at a subalpine forest dynamics plot in Southwest China

Tan

Luo

Hollingsworth

et al. 2018

Ecology and Evolution

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Although DNA barcoding has been widely used to identify plant species composition in temperate and tropical ecosystems, relatively few studies have used DNA barcodes to document both herbaceous and woody components of forest plot. A total of 201 species (72 woody species and 129 herbaceous species) representing 135 genera distributed across 64 families of seed plants were collected in a 25 ha CForBio subalpine forest dynamics plot. In total, 491 specimens were screened for three DNA regions of the chloroplast genome (rbcL, matK, and trnH‐psbA) as well as the internal transcribed spacers (ITS) of nuclear ribosomal DNA. We quantified species resolution for each barcode separately or in combination using a ML tree‐based method. Amplification and sequencing success were highest for rbcL, followed by trnH‐psbA, which performed better than ITS and matK. The rbcL + ITS barcode had slightly higher species resolution rates (88.60%) compared with rbcL + matK (86.60%) and rbcL + trnH‐psbA (86.01%). The addition of trnH‐psbA or ITS to the rbcL + matK barcode only marginally increased species resolution rates, although in combination the four barcodes had the highest discriminatory power (90.21%). The situations where DNA barcodes did not discriminate among species were typically associated with higher numbers of co‐occurring con‐generic species. In addition, herbaceous species were much better resolved than woody species. Our study represents one of the first applications of DNA barcodes in a subalpine forest dynamics plot and contributes to our understanding of patterns of genetic divergence among woody and herbaceous plant species.

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“…Recently, molecular phylogenetic analyses have widely been used in phylogenetic research, cryptic species identification, traditional medicinal plant authentication, and culture diversity conservation ( Hebert et al, 2003 ; Han et al, 2016 ; Li et al, 2016 ; Dong et al, 2017 ; Dechbumroong et al, 2018 ; Guo et al, 2018 ). Researchers have identified some cryptic species and new species by DNA barcoding, and their results were consistent with the folk taxonomic designations of local people ( Ragupathy et al, 2009 ; Newmaster and Ragupathy, 2010 ; Sui et al, 2011 ; Gao et al, 2017 ; Ji et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

From Folk Taxonomy to Species Confirmation of Acorus (Acoraceae): Evidences Based on Phylogenetic and Metabolomic Analyses

et al. 2020

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Plants in Acorus have been used as herbal medicine by various linguistic groups for thousands of years. Arguments of taxonomy of Acorus among scientists resulted in confusions and misuses of Acorus plants. The present study used different methods to investigate the classification of the genus, based on folk taxonomy. The relationships among Acorus species were revealed through phylogenetic analyses by constructing the Maximum Likelihood and Bayesian phylogenetic analyses based on sequences of two chloroplast regions (trnL-trnF and rbcL). All samples named with two so-called synonyms, Acorus macrospadiceus (Yamam.) F. N. Wei and Y. K. Li and Acorus tatarinowii Schott collected from different habitats, were clustered into separate groups, which revealed that they represented two independent species. Multivariate statistical analysis of metabolites from different Acorus populations were carried out based on UPLC-QTOF-MS data. Three independent analysis, principal component analysis, heat-map analysis, and hierarchical cluster analysis, showed that A. macrospadiceus and A. tatarinowii are different from two recognized species in the genus, A. calamus L. and A. gramineus Aiton. The results of phylogenetics and chemotaxonomy, together with morphological and ecological evidences, were consistent with traditional knowledge of local people related to Acorus taxa, which proved the significance of parataxonomy. Multiple evidences including morphological, ecological, folk taxonomic, phylogenetic, and chemical taxonomic results suggested that there are four species in the genus Acorus.

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Efficient Identification of the Forest Tree Species in Aceraceae Using DNA Barcodes

Cited by 30 publications

References 50 publications

Plastome comparative genomics in maples resolves the infrageneric backbone relationships

Plastome comparative genomics in maples resolves the infrageneric backbone relationships

DNA barcoding herbaceous and woody plant species at a subalpine forest dynamics plot in Southwest China

From Folk Taxonomy to Species Confirmation of Acorus (Acoraceae): Evidences Based on Phylogenetic and Metabolomic Analyses

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