The Internal Transcribed Spacer (ITS) Region and trnhH-psbA Are Suitable Candidate Loci for DNA Barcoding of Tropical Tree Species of India

Background

DNA barcoding as a tool for species identification has been successful in animals and other organisms, including certain groups of plants. The exploration of this new tool for species identification, particularly in tree species, is very scanty from biodiversity-rich countries like India. rbcL and matK are standard barcode loci while ITS, and trnH-psbA are considered as supplementary loci for plants.

Methodology and Principal Findings

Plant barcode loci, namely, rbcL, matK, ITS, trnH-psbA, and the recently proposed ITS2, were tested for their efficacy as barcode loci using 300 accessions of tropical tree species. We tested these loci for PCR, sequencing success, and species discrimination ability using three methods. rbcL was the best locus as far as PCR and sequencing success rate were concerned, but not for the species discrimination ability of tropical tree species. ITS and trnH-psbA were the second best loci in PCR and sequencing success, respectively. The species discrimination ability of ITS ranged from 24.4 percent to 74.3 percent and that of trnH-psbA was 25.6 percent to 67.7 percent, depending upon the data set and the method used. matK provided the least PCR success, followed by ITS2 (59. 0%). Species resolution by ITS2 and rbcL ranged from 9.0 percent to 48.7 percent and 13.2 percent to 43.6 percent, respectively. Further, we observed that the NCBI nucleotide database is poorly represented by the sequences of barcode loci studied here for tree species.

Conclusion

Although a conservative approach of a success rate of 60–70 percent by both ITS and trnH-psbA may not be considered as highly successful but would certainly help in large-scale biodiversity inventorization, particularly for tropical tree species, considering the standard success rate of plant DNA barcode program reported so far. The recommended matK and rbcL primers combination may not work in tropical tree species as barcode markers.     

Evaluation of chloroplast and nuclear DNA barcodes for species identification in Terminalia L.

The genus Terminalia L. belongs to the Combretaceae family, which includes several medicinal and threatened species with high trade value. Species of Terminalia in India belong to four sections and species identification within the sections is considered to be complex due to the lack of sufficient taxonomical characters and the existence of morphotypes. Therefore, we tested the effectiveness of three chloroplast DNA barcodes (rbcL, matK, and trnH-psbA) and a nuclear DNA barcode (ITS2) for the discrimination of Terminalia species. A reference DNA barcode library consisting of 120 DNA barcodes from ten species of Terminalia was created. Intra-specific divergence was not observed among the accessions for any marker. Inter-specific divergence was highest in trnH-psbA (10.6%), followed by ITS2, matK and rbcL markers. The success of species differentiation by DNA barcodes was 100% with trnH-psbA, 80% with matK and ITS2, and 10% with rbcL. In the phylogenetic trees, the rbcL marker did not differentiate the species in any section. Two species from the section Catappa were not differentiated by matK and ITS2 markers. Only trnH-psbA resolved all the species and ranked the best among four markers for species identification. However, regarding species relationship studies, ITS2 was found to be better than other markers because it formed a separate clade for each section.     

A DNA barcode reference library for the native woody seed plants of Japan

DNA barcode databases are increasingly available for a range of organisms, facilitating the wide application of DNA barcode-based studies. Here we announce the development of a comprehensive DNA barcode reference library of Japanese native woody seed plants representing 43 orders, 99 families, 303 genera and 834 species, and comprising 77.3% of the genera and 72.2% of the species of native woody seed plants in Japan. A total of 6216 plant specimens were collected from 223 sites across the subtropical, temperate, boreal and alpine biomes in Japan with most species represented by multiple accessions. This reference library utilized three chloroplast DNA regions (rbcL, trnH-psbA and matK) and consists of 14,403 barcode sequences. Individual regions varied in their identification rates, with species-level and genus-level rates for rbcL, trnH-psbA and matK based on blast being 57.4%/96.2%, 78.5%/99.1% and 67.8%/98.1%, respectively. Identification rates were higher using region combinations, with total species-level rates for two region combinations (rbcL & trnH-psbA, rbcL & matK and trnH-psbA & matK) ranging between 90.6% and 95.8%, and for all three regions being equal to 98.6%. Genus-level identification rates were even higher, ranging between 99.7% and 100% for two region combinations and being 100% for the three regions. These results indicate that this DNA barcode reference library is an effective resource for investigations of native woody seed plants in Japan using DNA barcodes and provides a useful template for the development of libraries for other components of the Japanese flora.     

DNA Barcode Authentication of Wood Samples of Threatened and Commercial Timber Trees within the Tropical Dry Evergreen Forest of India

Background

India is rich with biodiversity, which includes a large number of endemic, rare and threatened plant species. Previous studies have used DNA barcoding to inventory species for applications in biodiversity monitoring, conservation impact assessment, monitoring of illegal trading, authentication of traded medicinal plants etc. This is the first tropical dry evergreen forest (TDEF) barcode study in the World and the first attempt to assemble a reference barcode library for the trees of India as part of a larger project initiated by this research group.

Methodology/Principal Findings

We sampled 429 trees representing 143 tropical dry evergreen forest (TDEF) species, which included 16 threatened species. DNA barcoding was completed using rbcL and matK markers. The tiered approach (1^st tier rbcL; 2^nd tier matK) correctly identified 136 out of 143 species (95%). This high level of species resolution was largely due to the fact that the tree species were taxonomically diverse in the TDEF. Ability to resolve taxonomically diverse tree species of TDEF was comparable among the best match method, the phylogenetic method, and the characteristic attribute organization system method.

Conclusions

We demonstrated the utility of the TDEF reference barcode library to authenticate wood samples from timber operations in the TDEF. This pilot research study will enable more comprehensive surveys of the illegal timber trade of threatened species in the TDEF. This TDEF reference barcode library also contains trees that have medicinal properties, which could be used to monitor unsustainable and indiscriminate collection of plants from the wild for their medicinal value.     

rbcL and matK earn two thumbs up as the core DNA barcode for ferns

Background

DNA barcoding will revolutionize our understanding of fern ecology, most especially because the accurate identification of the independent but cryptic gametophyte phase of the fern''s life history—an endeavor previously impossible—will finally be feasible. In this study, we assess the discriminatory power of the core plant DNA barcode (rbcL and matK), as well as alternatively proposed fern barcodes (trnH-psbA and trnL-F), across all major fern lineages. We also present plastid barcode data for two genera in the hyperdiverse polypod clade—Deparia (Woodsiaceae) and the Cheilanthes marginata group (currently being segregated as a new genus of Pteridaceae)—to further evaluate the resolving power of these loci.

Principal Findings

Our results clearly demonstrate the value of matK data, previously unavailable in ferns because of difficulties in amplification due to a major rearrangement of the plastid genome. With its high sequence variation, matK complements rbcL to provide a two-locus barcode with strong resolving power. With sequence variation comparable to matK, trnL-F appears to be a suitable alternative barcode region in ferns, and perhaps should be added to the core barcode region if universal primer development for matK fails. In contrast, trnH-psbA shows dramatically reduced sequence variation for the majority of ferns. This is likely due to the translocation of this segment of the plastid genome into the inverted repeat regions, which are known to have a highly constrained substitution rate.

Conclusions

Our study provides the first endorsement of the two-locus barcode (rbcL+matK) in ferns, and favors trnL-F over trnH-psbA as a potential back-up locus. Future work should focus on gathering more fern matK sequence data to facilitate universal primer development.     

Study of molecular genetic diversity and evolutionary history of medicinally important endangered genus Chlorophytum using DNA barcodes

This study was aimed to authenticate and present phylogenetic relationship among 19 species of genus Chlorophytum using DNA barcoding. In all, 107 accessions were analyzed with eight plastid (matK, rbcL, trnH-psbA, rpoC1, ycf5, rpoB, atp and psbK-psbI) and six nuclear (ITS) markers. The matK and rbcL were found to be ideal markers for identification and discrimination of Chlorophytum species. Phylogenetic analysis based on matK and rbcL sequences resolved the species in two major clades. All markers, except matK and rbcL, showed ambiguous reads and paralogy in analysis. DGGE analysis showed the presence of pseudogenes and/or co-amplification in these markers, which caused poor sequence quality. Phylogeny and probable evolution of genus Chlorophytum was proposed on the basis of cytological, morphological and genetic information.     

DNA barcoding: a tool for improved taxon identification and detection of species diversity

Recently it was decided that portions of rbcL and matK gene regions are approved and required standard barcode regions for land plants. Ideally, DNA barcoding can provide a fast and reliable way to identify species. Compiling a library of barcodes can be enhanced by the numerous specimens available in botanic gardens, museums and herbaria and in other ex situ conservation collections. Barcoding can strengthen ongoing efforts of botanic gardens and ex situ conservation collections to preserve Earth’s biodiversity. Our study aimed to detect the usability of the universal primers of the standard DNA barcode, to produce standard barcodes for species identification and to detect the discriminatory power of the standard barcode in a set of different groups of plant and fungal taxa. We studied Betula species originating from different parts of the world, and Salix taxa, bryophytes and edible and poisonous fungal species originating from Finland. In Betula and Salix, the standard DNA barcode regions, portions of matK and rbcL, were able to identify species to genus level, but did not show adequate resolution for species discrimination. Thus, supplementary barcode regions are needed for species identification. In Salix, the trnH-psbA spacer was also used, and it proved to have more resolution but, yet, not adequate levels of interspecific divergence for all studied taxa. In a set of bryophyte species, the rbcL gene region was found to possess adequate resolution for species discrimination for most genera studied. In bryophytes, matK failed to amplify properly. In fungi, the combination of ITS1 and ITS2 proved to be effective for species discrimination, although alignment difficulties were encountered. In general, closely related or recently diverged species are the greatest challenge, and the problem is most difficult in plants, both in terms of a suitable combination of barcoding regions and the universality of used primers.     

DNA barcoding of Orchidaceae in Korea

Species of Orchidaceae are under severe threat of extinction mainly due to overcollection and habitat destruction; accurate identification of orchid species is critical in conservation biology and sustainable utilization of orchids as plant resources. We examined 647 sequences of the cpDNA regions rbcL, matK, atpF‐atpH IGS, psbK‐psbI IGS and trnH‐psbA IGS from 89 orchid species (95 taxa) and four outgroup taxa to develop an efficient DNA barcode for Orchidaceae in Korea. The five cpDNA barcode regions were successfully amplified and sequenced for all chlorophyllous taxa, but the amplification and sequencing of the same regions in achlorophyllous taxa produced variable results. psbK‐psbI IGS showed the highest mean interspecific K2P distance (0.1192), followed by matK (0.0803), atpF‐atpH IGS (0.0648), trnH‐psbA IGS (0.0460) and rbcL (0.0248). The degree of species resolution for individual barcode regions ranged from 60.5% (rbcL) to 83.5% (trnH‐psbA IGS). The degree of species resolution was significantly enhanced in multiregion combinations of the five barcode regions. Of the 26 possible combinations of the five regions, six provided the highest degree of species resolution (98.8%). Among these, a combination of atpF‐atpH IGS, psbK‐psbI IGS and trnH‐psbA IGS, which comprises the least number of DNA regions, is the best option for barcoding of the Korean orchid species.     

DNA barcoding and haplotyping in different species of Andrographis

The genus Andrographis, belonging to the family Acanthaceae, contains several species of medicinal importance. Species, such as Andrographis alata, Andrographis echioides, Andrographis glandulosa, Andrographis lineata, Andrographis nallamalayana and Andrographis paniculata, with several bio-active compounds are being extensively used in folk medicine. However, difference of opinion exists with regard to inclusion of the species echioides into the genus Andrographis. The present study, using rbcL and matK sequences, for the first time established DNA barcodes for these six species. The nucleotide sequence of rbcL provided species-specific haplotypes for A. alata, A. lineata, and A. paniculata. Despite the differences with regard to nucleotide sequence, all the six species showed conserved amino acid sequence. However, all the six species showed distinct haplotypes in nucleotide sequence of matK and facilitated the identification and discrimination of these species. The phylogenetic tree generated with combined sequence of rbcL and matK revealed grouping of all the six species into a single clade confirming the positioning of the species echioides into the genus Andrographis.     

Evaluation of Four Commonly Used DNA Barcoding Loci for Chinese Medicinal Plants of the Family Schisandraceae

Many species of Schisandraceae are used in traditional Chinese medicine and are faced with contamination and substitution risks due to inaccurate identification. Here, we investigated the discriminatory power of four commonly used DNA barcoding loci (ITS, trnH-psbA, matK, and rbcL) and corresponding multi-locus combinations for 135 individuals from 33 species of Schisandraceae, using distance-, tree-, similarity-, and character-based methods, at both the family level and the genus level. Our results showed that the two spacer regions (ITS and trnH-psbA) possess higher species-resolving power than the two coding regions (matK and rbcL). The degree of species resolution increased with most of the multi-locus combinations. Furthermore, our results implied that the best DNA barcode for the species discrimination at the family level might not always be the most suitable one at the genus level. Here we propose the combination of ITS+trnH-psbA+matK+rbcL as the most ideal DNA barcode for discriminating the medicinal plants of Schisandra and Kadsura, and the combination of ITS+trnH-psbA as the most suitable barcode for Illicium species. In addition, the closely related species Schisandra rubriflora Rehder & E. H. Wilson and Schisandra grandiflora Hook.f. & Thomson, were paraphyletic with each other on phylogenetic trees, suggesting that they should not be distinct species. Furthermore, the samples of these two species from the southern Hengduan Mountains region formed a distinct cluster that was separated from the samples of other regions, implying the presence of cryptic diversity. The feasibility of DNA barcodes for identification of geographical authenticity was also verified here. The database and paradigm that we provide in this study could be used as reference for the authentication of traditional Chinese medicinal plants utilizing DNA barcoding.     

Plant core DNA barcode performance at a local scale: identification of the conifers of the state of Hidalgo,Mexico

DNA barcoding constitutes a fundamental tool for species identification, especially for highly diverse geographic regions. Here, we characterize and evaluate the plant core barcoding regions matK and rbcL to identify the 25 conifer species from the state of Hidalgo, Mexico, including 10 species in various threat categories. Sequence quality, linguistic complexity, and the presence of the barcode gap were estimated. Two methods were compared for successful species identification: BRONX (Barcode Recognition Obtained with Nucleotide eXposés) and the least inclusive clade. We generated 77 sequences for matK and 88 for rbcL. The matK region had higher haplotype diversity and nucleotide diversity (Π), including six indels. The analysis of 77 specimens with complete sequences (matK + rbcL) resulted in 21 nonspecies-specific unique haplotypes for the 25 conifer species. Higher sequence quality and linguistic complexity were observed in rbcL than in matK. Every diagnosable species had a barcode gap. Ninety-seven specimens were assigned unambiguously to family and genus, regardless of the marker or method employed. The analysis of matK with BRONX produced the highest species level identification success (44%). Despite the low specimen identification success at the specific level, it will be possible to establish local management, conservation, and monitoring projects for at least half of the threatened species even when specimens do not exhibit diagnostic morphological characters. The low divergence between closely related species may result from the slow rate of molecular evolution of the core barcoding markers or from hybridization or incomplete lineage sorting. Similar identification success is expected for groups with comparable life history traits under similar conditions as this study. A reduction in the geographic area will not necessarily translate into higher identification success, especially for high-diversity regions and centres of diversification.     

Speciation slowing down in widespread and long-living tree taxa: insights from the tropical timber tree genus Milicia (Moraceae)

The long generation time and large effective size of widespread forest tree species can result in slow evolutionary rate and incomplete lineage sorting, complicating species delimitation. We addressed this issue with the African timber tree genus Milicia that comprises two morphologically similar and often confounded species: M. excelsa, widespread from West to East Africa, and M. regia, endemic to West Africa. We combined information from nuclear microsatellites (nSSRs), nuclear and plastid DNA sequences, and morphological systematics to identify significant evolutionary units and infer their evolutionary and biogeographical history. We detected five geographically coherent genetic clusters using nSSRs and three levels of genetic differentiation. First, one West African cluster matched perfectly with the morphospecies M. regia that formed a monophyletic clade at both DNA sequences. Second, a West African M. excelsa cluster formed a monophyletic group at plastid DNA and was more related to M. regia than to Central African M. excelsa, but shared many haplotypes with the latter at nuclear DNA. Third, three Central African clusters appeared little differentiated and shared most of their haplotypes. Although gene tree paraphyly could suggest a single species in Milicia following the phylogenetic species concept, the existence of mutual haplotypic exclusivity and nonadmixed genetic clusters in the contact area of the two taxa indicate strong reproductive isolation and, thus, two species following the biological species concept. Molecular dating of the first divergence events showed that speciation in Milicia is ancient (Tertiary), indicating that long-living tree taxa exhibiting genetic speciation may remain similar morphologically.     

Is DNA barcoding child's play? Science education and the utility of DNA barcoding for the discrimination of UK tree species

We present the findings of a DNA barcoding study of the UK tree flora, implemented as part of an innovative, research‐based science education programme called ‘Tree School’. The UK tree flora comprises native and introduced species, and is a taxonomically diverse study group for the exploration of the potential and limitations of DNA barcoding. The children participating in the project collected voucher specimens and generated DNA barcode sequences from trees and shrubs found in the grounds and surrounding woodlands of a residential field centre in Dorset, UK. We assessed the potential of rbcL and matK markers for amplification and DNA sequencing success and for species discrimination among the 67 tree and shrub species included in this study. Although we achieved 100% PCR amplification and sequencing success for rbcL and matK, mononucleotide repeats affected sequence quality in matK for some taxonomic groups (e.g. Rosaceae). Species discrimination success ranged from 65% to 71% using tree‐based methods to 86% using BLASTN. The occurrence of known hybrids (diploid and polyploid) and their progenitors on the study site reduced the overall species discrimination success for both loci. This study demonstrates that, even in a floristic context, rbcL and matK alone are insufficient for the discrimination of UK tree species, especially where taxonomically complex groups are present. From a science education perspective, DNA barcoding represents a compelling and accessible platform for the engagement of non‐experts in ongoing research, providing an opportunity for them to contribute authentic scientific data to an international research campaign.     

Utility of indels for species-level identification of a biologically complex plant group: a study with intergenic spacer in Citrus

The Consortium of Barcode of Life plant working group proposed to use the defined portion of plastid genes rbcL and matK either singly or in combination as the standard DNA barcode for plants. But DNA barcode based identification of biologically complex plant groups are always a challenging task due to the occurrence of natural hybridization. Here, we examined the use of indels polymorphism in trnH-psbA and trnL-trnF sequences for rapid species identification of citrus. DNA from young leaves of selected citrus species were isolated and matK gene (~800 bp) and trnH-psbA spacer (~450 bp) of Chloroplast DNA was amplified for species level identification. The sequences within the group taxa of Citrus were aligned using the ClustalX program. With few obvious misalignments were corrected manually using the similarity criterion. We identified a 54 bp inverted repeat or palindrome sequence (27–80 regions) and 6 multi residues indel coding regions. Large inverted repeats in cpDNA provided authentication at the higher taxonomic levels. These diagnostics indel marker from trnH-psbA were successful in identifying different species (5 out of 7) within the studied Citrus except Citrus limon and Citrus medica. These two closely related species are distinguished through the 6 bp deletion in trnL-trnF. This study demonstrated that the indel polymorphism based approach easily characterizes the Citrus species and the same may be applied in other complex groups. Likewise other indels occurring intergenic spacer of chloroplast regions may be tested for rapid identification of other secondary citrus species.     

DNA Barcoding of Rhodiola (Crassulaceae): A Case Study on a Group of Recently Diversified Medicinal Plants from the Qinghai-Tibetan Plateau

DNA barcoding, the identification of species using one or a few short standardized DNA sequences, is an important complement to traditional taxonomy. However, there are particular challenges for barcoding plants, especially for species with complex evolutionary histories. We herein evaluated the utility of five candidate sequences — rbcL, matK, trnH-psbA, trnL-F and the internal transcribed spacer (ITS) — for barcoding Rhodiola species, a group of high-altitude plants frequently used as adaptogens, hemostatics and tonics in traditional Tibetan medicine. Rhodiola was suggested to have diversified rapidly recently. The genus is thus a good model for testing DNA barcoding strategies for recently diversified medicinal plants. This study analyzed 189 accessions, representing 47 of the 55 recognized Rhodiola species in the Flora of China treatment. Based on intraspecific and interspecific divergence and degree of monophyly statistics, ITS was the best single-locus barcode, resolving 66% of the Rhodiola species. The core combination rbcL+matK resolved only 40.4% of them. Unsurprisingly, the combined use of all five loci provided the highest discrimination power, resolving 80.9% of the species. However, this is weaker than the discrimination power generally reported in barcoding studies of other plant taxa. The observed complications may be due to the recent diversification, incomplete lineage sorting and reticulate evolution of the genus. These processes are common features of numerous plant groups in the high-altitude regions of the Qinghai-Tibetan Plateau.     

Applying DNA barcodes for identification of plant species in the family Araliaceae

An effective DNA marker in authentication of the family Araliaceae was screened out of the five DNA regions (matK, rbcL, ITS2, psbA-trnH and ycf5). In the present study, 1113 sequences of 276 species from 23 genera (Araliaceae) were collected from DNA sequencing and GenBank, in which 16 specimens were from 5 provinces in China and Japan. All of the sequences were assessed in the success rates of PCR amplifications, intra- and inter-specific divergence, DNA barcoding gaps and efficiency of identification. Compared with other markers, ITS2 showed superiority in species discrimination with an accurate identification of 85.23% and 97.29% at the species and genus levels, respectively, in plant samples from the 589 sequences derived from Araliaceae. Consequently, as one of the most popular phylogenetic markers, our study indicated that ITS2 was a powerful barcode for Araliaceae identification.     

Phylogenetic study of Oryzoideae species and related taxa of the Poaceae based on <Emphasis Type="Italic">atpB</Emphasis>-<Emphasis Type="Italic">rbcL</Emphasis> and <Emphasis Type="Italic">ndhF</Emphasis> DNA sequences

Oryzoideae (Poaceae) plants have economic and ecological value. However, the phylogenetic position of some plants is not clear, such as Hygroryza aristata (Retz.) Nees. and Porteresia coarctata (Roxb.) Tateoka (syn. Oryza coarctata). Comprehensive molecular phylogenetic studies have been carried out on many genera in the Poaceae. The different DNA sequences, including nuclear and chloroplast sequences, had been extensively employed to determine relationships at both higher and lower taxonomic levels in the Poaceae. Chloroplast DNA ndhF gene and atpB-rbcL spacer were used to construct phylogenetic trees and estimate the divergence time of Oryzoideae, Bambusoideae, Panicoideae, Pooideae and so on. Complete sequences of atpB-rbcL and ndhF were generated for 17 species representing six species of the Oryzoideae and related subfamilies. Nicotiana tabacum L. was the outgroup species. The two DNA datasets were analyzed, using Maximum Parsimony and Bayesian analysis methods. The molecular phylogeny revealed that H. aristata (Retz.) Nees was the sister to Chikusichloa aquatica Koidz. Moreover, P. coarctata (Roxb.) Tateoka was in the genus Oryza. Furthermore, the result of evolution analysis, which based on the ndhF marker, indicated that the time of origin of Oryzoideae might be 31 million years ago.     

Validation of the ITS2 Region as a Novel DNA Barcode for Identifying Medicinal Plant Species

Background

The plant working group of the Consortium for the Barcode of Life recommended the two-locus combination of rbcL + matK as the plant barcode, yet the combination was shown to successfully discriminate among 907 samples from 550 species at the species level with a probability of 72%. The group admits that the two-locus barcode is far from perfect due to the low identification rate, and the search is not over.

Methodology/Principal Findings

Here, we compared seven candidate DNA barcodes (psbA-trnH, matK, rbcL, rpoC1, ycf5, ITS2, and ITS) from medicinal plant species. Our ranking criteria included PCR amplification efficiency, differential intra- and inter-specific divergences, and the DNA barcoding gap. Our data suggest that the second internal transcribed spacer (ITS2) of nuclear ribosomal DNA represents the most suitable region for DNA barcoding applications. Furthermore, we tested the discrimination ability of ITS2 in more than 6600 plant samples belonging to 4800 species from 753 distinct genera and found that the rate of successful identification with the ITS2 was 92.7% at the species level.

Conclusions

The ITS2 region can be potentially used as a standard DNA barcode to identify medicinal plants and their closely related species. We also propose that ITS2 can serve as a novel universal barcode for the identification of a broader range of plant taxa.     

Molecular phylogenetics of Uvaria (Annonaceae): relationships with Balonga,Dasoclema and Australian species of Melodorum

An extended molecular phylogenetic analysis of Uvaria (Annonaceae) is presented, using maximum parsimony, maximum likelihood and Bayesian methods, based on sequences of four plastid DNA regions (matK, psbA‐trnH spacer, rbcL and trnL‐F). The additional taxa include the monotypic West African genus Balonga, the monotypic South‐East Asian genus Dasoclema and seven Australian representatives of the genus Melodorum. The results indicate that all of these taxa are nested within a well‐supported clade otherwise consisting of Uvaria species, indicating that their taxonomic treatment needs to be reassessed. The distinguishing morphological characteristics of the taxa are re‐evaluated and interpreted as specialized adaptations of the basic Uvaria structure. The genus Uvaria is accordingly extended following the transfer of these species, necessitating six new nomenclatural combinations and two replacement names. © 2010 The Linnean Society of London, Botanical Journal of the Linnean Society, 2010, 163 , 33–43.     

DNA barcoding of Gaultheria L. in China (Ericaceae: Vaccinioideae)

Abstract Four DNA barcoding loci, chloroplast loci rbcL, matK, trnH‐psbA, and nuclear locus internal transcribed spacer (ITS), were tested for the accurate discrimination of the Chinese species of Gaultheria by using intraspecific and interspecific pairwise P‐distance, Wilcoxon signed rank test, and tree‐based analyses. This study included 186 individuals from 89 populations representing 30 species. For all individuals, single locus markers showed high levels of sequencing universality but were ineffective for species resolvability. Polymerase chain reaction amplification and sequencing were successful for all four loci. Both ITS and matK showed significantly higher levels of interspecific species delimitation than rbcL and trnH‐psbA. A combination of matK and ITS was the most efficient DNA barcode among all studied regions, however, they do not represent an appropriate candidate barcode for Chinese Gaultheria, by which only 11 out of 30 species can be separated. Loci rbcL, matK, and trnH‐psbA, which were recently proposed as universal plant barcodes, have a very poor capacity for species separation for Chinese Gaultheria. DNA barcodes may be reliable tools to identify the evolutionary units of this group, so further studies are needed to develop more efficient DNA barcodes for Gaultheria and other genera with complicated evolutionary histories.