Shiliang Zhou

Comparative analysis of a large dataset indicates that internal transcribed spacer (ITS) should be incorporated into the core barcode for seed plants

A two-marker combination of plastid rbcL and matK has previously been recommended as the core plant barcode, to be supplemented with additional markers such as plastid trnH–psbA and nuclear ribosomal internal transcribed spacer (ITS). To assess the effectiveness and universality of these barcode markers in seed plants, we sampled 6,286 individuals representing 1,757 species in 141 genera of 75 families (42 orders) by using four different methods of data analysis. These analyses indicate that (i) the three plastid markers showed high levels of universality (87.1–92.7%), whereas ITS performed relatively well (79%) in angiosperms but not so well in gymnosperms; (ii) in taxonomic groups for which direct sequencing of the marker is possible, ITS showed the highest discriminatory power of the four markers, and a combination of ITS and any plastid DNA marker was able to discriminate 69.9–79.1% of species, compared with only 49.7% with rbcL + matK; and (iii) where multiple individuals of a single species were tested, ascriptions based on ITS and plastid DNA barcodes were incongruent in some samples for 45.2% of the sampled genera (for genera with more than one species sampled). This finding highlights the importance of both sampling multiple individuals and using markers with different modes of inheritance. In cases where it is difficult to amplify and directly sequence ITS in its entirety, just using ITS2 is a useful backup because it is easier to amplify and sequence this subset of the marker. We therefore propose that ITS/ITS2 should be incorporated into the core barcode for seed plants.

Highly variable chloroplast markers for evaluating plant phylogeny at low taxonomic levels and for DNA barcoding.

Background At present, plant molecular systematics and DNA barcoding techniques rely heavily on the use of chloroplast gene sequences. Because of the relatively low evolutionary rates of chloroplast genes, there are very few choices suitable for molecular studies on angiosperms at low taxonomic levels, and for DNA barcoding of species. Methodology/Principal Findings We scanned the entire chloroplast genomes of 12 genera to search for highly variable regions. The sequence data of 9 genera were from GenBank and 3 genera were of our own. We identified nearly 5% of the most variable loci from all variable loci in the chloroplast genomes of each genus, and then selected 23 loci that were present in at least three genera. The 23 loci included 4 coding regions, 2 introns, and 17 intergenic spacers. Of the 23 loci, the most variable (in order from highest variability to lowest) were intergenic regions ycf1-a, trnK, rpl32-trnL, and trnH-psbA, followed by trnSUGA-trnGUCC, petA-psbJ, rps16-trnQ, ndhC-trnV, ycf1-b, ndhF, rpoB-trnC, psbE-petL, and rbcL-accD. Three loci, trnSUGA-trnGUCC, trnT-psbD, and trnW-psaJ, showed very high nucleotide diversity per site (π values) across three genera. Other loci may have strong potential for resolving phylogenetic and species identification problems at the species level. The loci accD-psaI, rbcL-accD, rpl32-trnL, rps16-trnQ, and ycf1 are absent from some genera. To amplify and sequence the highly variable loci identified in this study, we designed primers from their conserved flanking regions. We tested the applicability of the primers to amplify target sequences in eight species representing basal angiosperms, monocots, eudicots, rosids, and asterids, and confirmed that the primers amplified the desired sequences of these species. Significance/Conclusions Chloroplast genome sequences contain regions that are highly variable. Such regions are the first consideration when screening the suitable loci to resolve closely related species or genera in phylogenetic analyses, and for DNA barcoding.

DNA Barcoding of Panax Species

Ginsengs (Panax, Araliaceae) are among the plants best known for their medicinal properties. Many ginseng species are endangered due to over-exploitation of natural resources - a situation difficult to remedy while there are no reliable, practical methods for species identification. We screened eleven candidate DNA barcoding loci to establish an accurate and effective Panax species identification system, both for commercial and conservation purposes. We used 95 ginseng samples, representing all the species in the genus. We found considerable differences in the performance of the potential barcoding regions. The sequencing of ATPF-ATPH was unsuccessful due to poly-N structures. The RBCL, RPOB, and RPOC1 regions were found to be mostly invariable, with only four to eight variable sites. Using MATK, PSBK-I, PSBM-TRND, RPS16 and NAD1, we could identify four to six out of eight considerably divergent species but only one to five out of nineteen clusters within the P. bipinnatifidus species group. PSBA-TRNH and ITS were the most variable loci, working very well both in species and cluster identifications. We demonstrated that the combination of PSBA-TRNH and ITS is sufficient for identifying all the species and clusters in the genus.

ycf1 , the most promising plastid DNA barcode of land plants

A DNA barcode is a DNA fragment used to identify species. For land plants, DNA fragments of plastid genome could be the primary consideration. Unfortunately, most of the plastid candidate barcodes lack species-level resolution. The identification of DNA barcodes of high resolution at species level is critical to the success of DNA barcoding in plants. We searched the available plastid genomes for the most variable regions and tested the best candidates using both a large number of tree species and seven well-sampled plant groups. Two regions of the plastid gene ycf1, ycf1a and ycf1b, were the most variable loci that were better than existing plastid candidate barcodes and can serve as a barcode of land plants. Primers were designed for the amplification of these regions, and the PCR success of these primers ranged from 82.80% to 98.17%. Of 420 tree species, 357 species could be distinguished using ycf1b, which was slightly better than the combination of matK and rbcL. For the well-sampled representative plant groups, ycf1b generally performed better than any of the matK, rbcL and trnH-psbA. We concluded that ycf1a or ycf1b is the most variable plastid genome region and can serve as a core barcode of land plants.

New universal matK primers for DNA barcoding angiosperms

Abstract  The chloroplast maturase K gene (matK) is one of the most variable coding genes of angiosperms and has been suggested to be a “barcode” for land plants. However, matK exhibits low amplification and sequencing rates due to low universality of currently available primers and mononucleotide repeats. To resolve these technical problems, we evaluated the entire matK region to find a region of 600–800 bp that is highly variable, represents the best of all matK regions with priming sites conservative enough to design universal primers, and avoids the mononucleotide repeats. After careful evaluation, a region in the middle was chosen and a pair of primers named matK472F and matK1248R was designed to amplify and sequence the matK fragment of approximately 776 bp. This region encompasses the most variable sites, represents the entire matK region best, and also exhibits high amplification rates and quality of sequences. The universality of this primer pair was tested using 58 species from 47 families of angiosperm plants. The primers showed a strong amplification (93.1%) and sequencing (92.6%) successes in the species tested. We propose that the new primers will solve, in part, the problems encountered when using matK and promote the adoption of matK as a DNA barcode for angiosperms.

Complete chloroplast genome of Sedum sarmentosum and chloroplast genome evolution in Saxifragales.

Comparative chloroplast genome analyses are mostly carried out at lower taxonomic levels, such as the family and genus levels. At higher taxonomic levels, chloroplast genomes are generally used to reconstruct phylogenies. However, little attention has been paid to chloroplast genome evolution within orders. Here, we present the chloroplast genome of Sedum sarmentosum and take advantage of several available (or elucidated) chloroplast genomes to examine the evolution of chloroplast genomes in Saxifragales. The chloroplast genome of S. sarmentosum is 150,448 bp long and includes 82,212 bp of a large single-copy (LSC) region, 16.670 bp of a small single-copy (SSC) region, and a pair of 25,783 bp sequences of inverted repeats (IRs).The genome contains 131 unique genes, 18 of which are duplicated within the IRs. Based on a comparative analysis of chloroplast genomes from four representative Saxifragales families, we observed two gene losses and two pseudogenes in Paeonia obovata, and the loss of an intron was detected in the rps16 gene of Penthorum chinense. Comparisons among the 72 common protein-coding genes confirmed that the chloroplast genomes of S. sarmentosum and Paeonia obovata exhibit accelerated sequence evolution. Furthermore, a strong correlation was observed between the rates of genome evolution and genome size. The detected genome size variations are predominantly caused by the length of intergenic spacers, rather than losses of genes and introns, gene pseudogenization or IR expansion or contraction. The genome sizes of these species are negatively correlated with nucleotide substitution rates. Species with shorter duration of the life cycle tend to exhibit shorter chloroplast genomes than those with longer life cycles.

Plant DNA barcoding in China

Identification is the keystone of biology (Bell,1986). However, to biologists and students of biology,the total numbers of species that must be identified faroutnumber the names commonly used in English, Chi-nese,orotherlivinglanguages.Inaddition,theidentifi-cation cues vary greatly between different taxonomicalgroups.Evenforthetaxonomistswithlongtrainingandexperience, it is difficult to remember all specific termsfor a given group, e.g., Orchidaceae or Poaceae, with-outhelpoffloristicbooksormonographs.Ittakesmuchtime and effort to train a taxonomist, at a time whenfewer and fewer young students are interested in this“classical”and“out-of-style”,butextremelyimportant,discipline. Many students elect to learn the more “ad-vanced” and “modern” biological disciples like molec-ular biology and biochemistry. Thus, in China and therest of the world, taxonomists are themselves becom-ing “endangered”. The rise of the DNA barcoding isexpected to mitigate, at least in part, this dilemma.The concept of DNA barcoding was proposed torapidly and accurately identify species by using short,standardized DNA markers (Arnot et al., 1993; Floydet al., 2002; Hebert et al., 2003). In fact, the idea ofspecies identification using molecular evidence datesback to 1982 for discerning the origin of fresh meats(Kang’ethe et al., 1982). Since 2003, the approachof DNA barcoding has been greatly promoted, mainlyby zoologists, to provide tools for the recognition ofspecies as an improvement on or supplement to tradi-tionalmorphology-basedtaxonomy(Hebertetal.,2003;

Nelumbonaceae: Systematic position and species diversification revealed by the complete chloroplast genome

Abstract  Nelumbonaceae is a morphologically unique family of angiosperms and was traditionally placed in Nymphaeales; more recently, it was placed in Proteales based on molecular data, or in an order of its own, Nelumbonales. To determine the systematic position of the family and to date the divergence time of the family and the divergence time of its two intercontinentally disjunct species, we sequenced the entire chloroplast genome of Nelumbo lutea and most of the chloroplast genes of N. nucifera. We carried out phylogenetic and molecular dating analyses of the two species and representatives of 47 other plant families, representing the major lineages of angiosperms, using 83 plastid genes. The N. lutea genome was 163 510 bp long, with a total of 130 coding genes and an overall GC content of 38%. No significant structural differences among the genomes of N. lutea, Nymphaea alba, and Platanus occidentalis were observed. The phylogenetic relationships based on the 83 plastid genes revealed a close relationship between Nelumbonaceae and Platanaceae. The divergence times were estimated to be 109 Ma between the two families and 1.5 Ma between the two Nelumbo species. The estimated time was only slightly longer than the age of known Nelumbo fossils, suggesting morphological stasis within Nelumbonaceae. We conclude that Nelumbonaceae holds a position in or close to Proteales. We further conclude that the two species of Nelumbo diverged recently from a common ancestor and do not represent ancient relicts on different continents.

Tree of life for the genera of Chinese vascular plants

We reconstructed a phylogenetic tree of Chinese vascular plants (Tracheophyta) using sequences of the chloroplast genes atpB, matK, ndhF, and rbcL and mitochondrial matR. We produced a matrix comprising 6098 species and including 13 695 DNA sequences, of which 1803 were newly generated. Our taxonomic sampling spanned 3114 genera representing 323 families of Chinese vascular plants, covering more than 93% of all genera known from China. The comprehensive large phylogeny supports most relationships among and within families recognized by recent molecular phylogenetic studies for lycophytes, ferns (monilophytes), gymnosperms, and angiosperms. For angiosperms, most families in Angiosperm Phylogeny Group IV are supported as monophyletic, except for a paraphyletic Dipterocarpaceae and Santalaceae. The infrafamilial relationships of several large families and monophyly of some large genera are well supported by our dense taxonomic sampling. Our results showed that two species of Eberhardtia are sister to a clade formed by all other taxa of Sapotaceae, except Sarcosperma. We have made our phylogeny of Chinese vascular plants publically available for the creation of subtrees via SoTree (http://www.darwintree.cn/flora/index.shtml), an automated phylogeny assembly tool for ecologists.

Accelerating plant DNA barcode reference library construction using herbarium specimens: improved experimental techniques

A well‐covered reference library is crucial for successful identification of species by DNA barcoding. The biggest difficulty in building such a reference library is the lack of materials of organisms. Herbarium collections are potentially an enormous resource of materials. In this study, we demonstrate that it is likely to build such reference libraries using the reconstructed (self‐primed PCR amplified) DNA from the herbarium specimens. We used 179 rosaceous specimens to test the effects of DNA reconstruction, 420 randomly sampled specimens to estimate the usable percentage and another 223 specimens of true cherries (Cerasus, Rosaceae) to test the coverage of usable specimens to the species. The barcode rbcLb (the central four‐sevenths of rbcL gene) and matK was each amplified in two halves and sequenced on Roche GS 454 FLX+. DNA from the herbarium specimens was typically shorter than 300 bp. DNA reconstruction enabled amplification fragments of 400–500 bp without bringing or inducing any sequence errors. About one‐third of specimens in the national herbarium of China (PE) were proven usable after DNA reconstruction. The specimens in PE cover all Chinese true cherry species and 91.5% of vascular species listed in Flora of China. It is very possible to build well‐covered reference libraries for DNA barcoding of vascular species in China. As exemplified in this study, DNA reconstruction and DNA‐labelled next‐generation sequencing can accelerate the construction of local reference libraries. By putting the local reference libraries together, a global library for DNA barcoding becomes closer to reality.