Plastome phylogenomics of Cephalotaxus (Cephalotaxaceae) and allied genera

Background and Aims Cephalotaxus is a paleo-endemic genus in East Asia that consists of about 7–9 conifer species. Despite its great economic and ecological importance, the relationships between Cephalotaxus and related genera, as well as the interspecific relationships within Cephalotaxus, have long been controversial, resulting in contrasting taxonomic proposals in delimitation of Cephalotaxaceae and Taxaceae. Based on plastome data, this study aims to reconstruct a robust phylogeny to infer the systematic placement and the evolutionary history of Cephalotaxus.MethodsA total of 11 plastomes, representing all species currently recognized in Cephalotaxus and two Torreya species, were sequenced and assembled. Combining these with previously published plastomes, we reconstructed a phylogeny of Cephalotaxaceae and Taxaceae with nearly full taxonomic sampling. Under a phylogenetic framework and molecular dating, the diversification history of Cephalotaxus and allied genera was explored.Key ResultsPhylogenetic analyses of 81 plastid protein-coding genes recovered robust relationships between Cephalotaxus and related genera, as well as providing a well-supported resolution of interspecific relationships within Cephalotaxus, Taxus, Torreya and Amentotaxus. Divergence time estimation indicated that most extant species of these genera are relatively young, although fossil and other molecular evidence consistently show that these genera are ancient plant lineages.ConclusionsOur results justify the taxonomic proposal that recognizes Cephalotaxaceae as a monotypic family, and contribute to a clear-cut delineation between Cephalotaxaceae and Taxaceae. Given that extant species of Cephalotaxus are derived from recent divergence events associated with the establishment of monsoonal climates in East Asia and Pleistocene climatic fluctuations, they are not evolutionary relics.     

The phylogenetic positions of the conifer genera Amentotaxus,Phyllocladus, and Nageia inferred from 18s rRNA sequences

To determine the evolutionary positions of the conifer genera Amentotaxus, Phyllocladus, and Nageia, we obtained 18S rRNA sequences from 11 new taxa representing the major living orders and families of gymnosperms. With the published Chlamydomonas as an outgroup, phylogenetic analyses of our new data and available sequences indicate that (1) the Gnetales form a monophyletic group, which is an outgroup to the conifers, (2) the conifers are monophyletic, (3) Taxaceae, Cephalotaxaceae, Cupressaceae, and Taxodiaceae form a monophyletic group, (4) Amentotaxus is closer to Torreya than to Cephalotaxus, suggesting that Amentotaxus is better to be classified as a member of Taxaceae, (5) Phyllocladus, Dacrycarpus, Podocarpus, and Nageia form a monophyletic group, and (6) Pinaceae is an outgroup to the other families of conifers. Our finding that Phyllocladus is a sister group of the Podocarpaceae disagrees with the suggestion that the phylloclade of the genus is an ancient structure and that the genus is a terminal taxon within the Podocarpaceae. The genus Nageia is more closely related to Podocarpus than to Dacrycarpus and was derived from within the Podocarpaceae. In conclusion, our data indicate that in conifers, the uniovulate cone occurred independently in Taxacaeae and Cephalotaxaceae, and in Podocarpaceae after the three families separated from Pinaceae, and support the hypothesis that the uniovulate cone is derived from reduction of a multiovulate cone.Correspondence to: S.-M. Chaw     

Phylogeny of Taxaceae and Cephalotaxaceae Genera Inferred from Chloroplast matK Gene and Nuclear rDNA ITS Region

Phylogeny of the Taxaceae genera and the monotypic family Cephalotaxaceae has been extraordinarily controversial. In this paper chloroplast matK genes and nuclear ITS sequences were determined for all six genera of the two families and representatives of other conifer families. Analysis using either the nonsynonymous sites or the deduced amino acid sequences of matK genes strongly indicates that taxad genera and Cephalotaxaceae are monophyletic, with the Taxodiaceae/Cupressaceae clade as their sister group. Cephalotaxus is basal to the taxad genera, among which two clades, Torreya/Amentotaxus and Taxus/Pseudotaxus/Austrotaxus, are resolved. They correspond to Janchen's two tribes, Torreyeae and Taxeae. In Taxeae, Austrotaxus is the first to branch off. Analyses of the nuclear ITS sequence data corroborated the topology of the matK gene tree. These results refute the views that Cephalotaxaceae has no alliance with Taxaceae and that Austrotaxus and Amentotaxus should be excluded from the Taxaceae. We estimated the divergence time between the Taxodiaceae/Cupressaceae and the Cephalotaxaceae/Taxaceae clades to be 192–230 Myr ago and the divergence time between taxads and Cephalotaxus to be 149–179 Myr ago. Soon after the latter divergence event, within 6–8 Myr, the two taxad tribes originated. In conclusion, our data do not support Florin's claim that taxads could be traced to Devonian psilophytes (359–395 Myr ago).     

Cladistic analysis of Taxaceae s. l.

Taxaceae s. l. is a wider concept of classification treating five genera of Taxaceae s. str. and Cephalotaxus together. Cephalotaxus is morphologically very similar to the five genera of Taxaceae s. str. Various models of classification for six genera have already been published. However, the phylogenetic position and genuine relationships of these genera and species are still confusing. A cladistic analysis of Taxaceae s. l. has been carried out to resolve the problem existing in their phylogeny and to provide a new approach regarding the relationships of these six genera. Parsimony analyses were based on 28 characters and eight genera including two outgroups Agathis and Sciadopitys. The most parsimonious tree retained with branch length 38 and 194 rearrangement trials. Consistency index was 0.68 and retention index was 0.66. Principally, two main clades were found: one represented by Austrotaxus forming the base of the tree and another by the remaining five genera. Taxus + Pseudotaxus clade split after Austrotaxus, and Cephalotaxus was sister to Torreya + Amentotaxus clade. Taxus + Pseudotaxus clade was supported by the highest bootstrap value. Finally, cladistic analysis does not support existence of Cephalotaxaceae. Therefore, it would be better to classify Cephalotaxus within Taxaceae s. l. with the other five genera.     

Interspecific relationships and origins of Taxaceae and Cephalotaxaceae revealed by partitioned Bayesian analyses of chloroplast and nuclear DNA sequences

The precise delimitation of Taxaceae and Cephalotaxaceae is not totally resolved. Some contradicting taxonomic proposals have been published, which demonstrates the difficulties in establishing a natural classification of the families and especially in proposing a relevant treatment within the genera Taxus and Cephalotaxus. The aims of this study are to contribute to the phylogeny and specific delineation of the two conifer families on the basis of molecular data. A cladistic analysis of the sequences of five chloroplast (matK, rbcL, trnL, trnL-trnF spacer, and psbA-trnH spacer) and one nuclear (ITS) molecular markers was carried out, both individually and in combination, by distance, parsimony, likelihood, and Bayesian methods. The results confirm that the two families are monophyletic. In the genus Taxus, T. floridana is the first-branching taxon; T. brevifolia and T. globosa cluster together and are sister to T. baccata; the endemic T. yunnanensis clusters with T. wallichiana in subclade B and is only distantly related with the other four Taxus species in China (subclade A); T. fuana is closer to T. baccata than to other Taxus species. Torreya jackii and A. formosana are the first-branching species within Torreya and Amentotaxus, respectively. C. koreana and C. wilsoniana could be treated as two varieties of C. harringtonia. The ancestral distribution area of Taxaceae and Cephalotaxaceae is restricted either to Southwest China or Southeast China by DIVA analysis. The relaxed molecular clock indicates that the deepest divergences in Taxus go back to the late-Cretaceous. psbA-trnH, rbcL third codon position, and matK first codon position contributed most to the separation of taxa in Discriminant function analysis. Our results confirm, on a basis of multiple molecular markers and a complete sampling of basic species, the suggested monophyly of Taxaceae and Cephalotaxaceae and propose interspecific relationships within each group, with profound nomenclatural and taxonomic implications. Combination of partitioned Bayesian analysis and likelihood-based methods produced a more robust phylogenetic hypothesis for the two studied families.     

Physicochemical evolution and positive selection of the gymnosperm matK proteins

It is not clear whether matK evolves under Darwinian selection. In this study, the gymnosperm Taxaceae, Cephalotaxaceae and Pinaceae were used to illustrate the physicochemical evolution, molecular adaptation and evolutionary dynamics of gene divergence in matKs. matK sequences were amplified from 27 Taxaceae and 12 Cephalotaxaceae species. matK sequences of 19 Pinaceae species were retrieved from GenBank. The phylogenetic tree was generated using conceptual-translated amino acid sequences. Selective influences were investigated using standard d _N/d _S ratio methods and more sensitive techniques investigating the amino acid property changes resulting from nonsynonymous replacements in a phylogenetic context. Analyses revealed the presence of positive selection in matKs (N-terminal region, RT domain and domain X) of Taxaceae and Pinaceae, and found positive destabilizing selection in N-terminal region and RT domain of Cephalotaxaceae matK. Moreover, various amino acid properties were found to be influenced by destabilizing positive selection. Amino acid sites relating to these properties and to different secondary structures were found and have the potential to affect group II intron maturase function. Despite the evolutionary constraint on the rapidly evolving matK, this protein evolves under positive selection in gymnosperm. Several regions of matK have experienced molecular adaptation which fine-tunes maturase performance.     

部分裸子植物叶片总蛋白分析

采用ＳＤＳ－ ＰＡＧＥ 技术, 分析了红豆杉科（Ｔａｘａｃｅａｅ） 植物南方红豆杉（ Ｔａｘｕｓ ｃｈｉｎｅｎｓｉｓｖａｒ－ ｍａｉｒｅｉ （Ｌｅｍｅｅ ｅｔ Ｌｅｖｌ－） Ｃｈｅｎｇ ｅｔ Ｌ－Ｋ－Ｆｕ） 、穗花杉（ Ａｍｅｎｔｏｔａｘｕｓ ａｒｇｏｔａｅｎｉａ （Ｈａｎｃｅ） Ｐｉｌ ｇｅｒ） 、云南穗花杉（ Ａ－ ｙｕｎｎａｎｅｎｓｉｓ Ｌｉ） 、白豆杉（ Ｐｓｅｕｄｏｔａｘｕｓｃｈｉｅｎｉｉ（Ｃｈｅｎｇ） Ｃｈｅｎｇ） 以及三尖杉科（Ｃｅｐｈａｌｏｔａｘａｃｅａｅ） 、植物三尖杉（ Ｃｅｐｈａｌｏｔａｘｕｓ ｆｏｒｔｕｎｅｉ Ｈｏｏｋ－ｆ－） 、粗榧（ Ｃ－ｓｉｎｅｎｓｉｓ （Ｒｅｈｄ－ｅｔＷｉｌｓ－） Ｌｉ） 、海南粗榧（ Ｃ－ｈａｉｎａｎｅｎｓｉｓ Ｌｉ） 、篦子三尖杉（ Ｃ－ｏｌｉｖｅｒｉ Ｍａｓｔ－） 和罗汉松科（Ｐｏｄｏｃａｒｐａｃｅａｅ） 、植 物罗汉松 （ Ｐｏｄｏｃａｒｐｕｓ ｍａｃｒｏｐｈｙｌｌｕｓ （ Ｔｈｕｎｂ－ ） Ｄ－Ｄｏｎ） 、鸡毛 松（ Ｐ－ｉｍｂｒｉｃａｔｕｓ Ｂｌ－） 、竹柏（ Ｐ－ ｎａｇｉ（Ｔｈｕｎｂ－） Ｚｏｌｌ） 、陆均松（ Ｄａｃｒｙｄｉｕｍ ｐｉｅｒｒｅｉ Ｈｉｃｋｅｌ） 共１２ 种植物的叶片蛋白, 在蛋白质水平上采用     

Diversity and evolution of leaf anatomical characters in Taxaceae <Emphasis Type="Italic">s.l.—</Emphasis>fluorescence microscopy reveals new delimitating characters

Taxaceae s.l. comprise six genera (including Cephalotaxus) and about 35 species; The present study aims to give new insights into the evolution of this family, especially into the phylogenetic position of Cephalotaxus. Moreover, only little is known about comparative leaf anatomy of this family and this study aims to expose and interpret the diversity and evolution of leaf anatomical characters and to assess their applicability to identify taxa at the generic and species level. A detailed phylogeny was reconstructed, using both maximum likelihood and Bayesian inference, with a combined dataset of four molecular markers from the plastid and nuclear genomes. Leaf sections from 132 specimens, representing 32 species and four varieties (fresh and herbarium material) were inspected, using fluorescence microscopy. Ancestral characters were reconstructed using Mesquite. The phylogenetic analyses provided full support for Cephalotaxus as sister group to Taxaceae s.str. Within the latter, two monophyletic tribes Taxeae (comprising Austrotaxus, Pseudotaxus, and Taxus) and Torreyeae (comprising Amentotaxus and Torreya) were fully supported. Fluorescence microscopy was shown to be very useful for identifying leaf tissues and their constitution. We were able to show that particularly sclerified tissues have highest potential for the discrimination of both freshly collected samples and rehydrated herbarium specimens at the generic and species level. A correlation between the presence of different sclereid types could be shown and sclereids were hypothesized to pose a primitive trait in the evolution of Taxaceae s.l. New identification keys were generated on the basis of leaf anatomical characters. The microscopic method presented here is applicable for further studies within gymnosperms and probably in angiosperms, as well.     

Comparative palynological and wood anatomical studies of Indian Taxus wallichiana Zucc., Cephalotaxus mannii Hook. and Cephalotaxus griffithii Hook.

A comparative study of Taxus wallichiana Zucc., Cephalotaxus mannii Hook. and Cephalotaxus griffithii Hook. of two families Taxaceae and Cephalotaxaceae has been carried out in detail to support the taxonomic existence of two families. The comparative studies have been carried out on the basis of wood anatomy and palynology. The anatomical properties of wood including the tracheids, ray parenchyma, axial parenchyma and number of cross-field pits have been described in detail. The palynological studies include the shape, size and ultrastructure of pollen grains. These studies give a taxonomic support for the recognition of two different genera of families Taxaceae and Cephalotaxaceae which are closely related.     

红豆杉科、三尖杉科和罗汉松科的实验分类学研究进展

红豆杉科、三尖杉科和罗汉松科的系统位置及系统发育关系长期以来都存有争议,本文对此三科在实验分类学方面的研究进展及趋势作了综述。     

Identification of SNP markers for inferring phylogeny in temperate bamboos (Poaceae: Bambusoideae) using RAD sequencing

Phylogenetic relationships among temperate species of bamboo are difficult to resolve, owing to both the challenge of detecting sufficiently variable markers and their polyploid history. Here, we use restriction site–associated DNA sequencing to identify candidate loci with fixed allelic differences segregating between and within two temperate species of bamboos: Arundinaria faberi and Yushania brevipaniculata. Approximately 27 million paired‐end sequencing reads were generated across four samples. From pooled data, we assembled 67 685 and 70 668 de novo contigs from partial overlap among paired‐end reads, with an average length of 240 and 241 bp for the two species, respectively, which were used to investigate functional classification of RAD tags in a blastx search. Analysed separately by population, we recovered 29 443 putatively orthologous RAD tags shared across the four sampled populations, containing 28 023 sequence variants, of which c. 13 000 are segregating between species, and c. 3000 segregating between populations within each species. Analyses based on these RAD tags yielded robust phylogenetic inferences, even with data set constructed from surprisingly few loci. This study illustrates the potential for reduced‐representation genome data to resolve difficult phylogenetic relationships in temperate bamboos.     

红豆杉科、三尖杉科和罗汉松科植物叶片结构的比较观察

扫描电镜和光镜下的叶表皮特征以及叶片解剖结构的研究结果,支持在红豆杉科内建立白豆杉属的处理方式;赞同在三尖杉属内建立篦子三尖杉组,叶片解剖结构方面,三尖杉科和红豆杉科的穗花杉属的相似之处颇多。而叶表皮形态特征方面又表现为三尖杉科和罗汉松科更加接近。反映了出了红豆杉科、三尖杉科和罗汉松科之间的密切而又复杂的系统关系。     

Orthology prediction at scalable resolution by phylogenetic tree analysis

Background  

Orthology is one of the cornerstones of gene function prediction. Dividing the phylogenetic relations between genes into either orthologs or paralogs is however an oversimplification. Already in two-species gene-phylogenies, the complicated, non-transitive nature of phylogenetic relations results in inparalogs and outparalogs. For situations with more than two species we lack semantics to specifically describe the phylogenetic relations, let alone to exploit them. Published procedures to extract orthologous groups from phylogenetic trees do not allow identification of orthology at various levels of resolution, nor do they document the relations between the orthologous groups.     

Chromosome‐level genome assembly of the greenfin horse‐faced filefish (Thamnaconus septentrionalis) using Oxford Nanopore PromethION sequencing and Hi‐C technology

The greenfin horse‐faced filefish, Thamnaconus septentrionalis, is a valuable commercial fish species that is widely distributed in the Indo‐West Pacific Ocean. This fish has characteristic blue–green fins, rough skin and a spine‐like first dorsal fin. Thamnaconus septentrionalis is of conservation concern because its population has declined sharply, and it is an important marine aquaculture fish species in China. Genomic resources for the filefish are lacking, and no reference genome has been released. In this study, the first chromosome‐level genome of T. septentrionalis was constructed using nanopore sequencing and Hi‐C technology. A total of 50.95 Gb polished nanopore sequences were generated and were assembled into a 474.31‐Mb genome, accounting for 96.45% of the estimated genome size of this filefish. The assembled genome contained only 242 contigs, and the achieved contig N50 was 22.46 Mb, a surprisingly high value among all sequenced fish species. Hi‐C scaffolding of the genome resulted in 20 pseudochromosomes containing 99.44% of the total assembled sequences. The genome contained 67.35 Mb of repeat sequences, accounting for 14.2% of the assembly. A total of 22,067 protein‐coding genes were predicted, 94.82% of which were successfully annotated with putative functions. Furthermore, a phylogenetic tree was constructed using 1,872 single‐copy orthologous genes, and 67 unique gene families were identified in the filefish genome. This high‐quality assembled genome will be a valuable resource for a range of future genomic, conservation and breeding studies of T. septentrionalis.     

The course of resin canals in the shoots of conifers

The course of resin canals in stem cortex and the continuity between resin canals in leaves and those in stem cortex were investigated. The present paper is the first of three parts of the investigation. In this paper, fundamental features of resin canals and actual resin canal patterns in the Taxaceae, Cephalotaxaceae and Podocarpaceae are reported. From the observation of serial transections of shoots, composite diagrams and three-dimensional models of resin canal patterns are drawn. Central canals, if present, run vertically in stem cortex and sometimes divide, end blindly or unite each other. The distance between two adjacent central canals fluctuates rhythmically in connection with the vascular supply from the stem to leaves. The resin canal patterns of the families are classified into four types. Those ofTaxus, Nothotaxus and three species ofDacrydium belong to the Taxus type, those ofTorreya andCephalotaxus to the Torreya type, those ofDacrydium elatum, Podocarpus alpinus, P. elatus, P. elongatus andP. neriifolius to the Dacrydium type, those ofP. macrophyllus, P. nagi andP. koordersii to the Podocarpus type.     

Evolution of the Chloroplast trnL-trnF Region in the Gymnosperm Lineages Taxaceae and Cephalotaxaceae

The trnL-trnF region is located in the large single-copy region of the chloroplast genome. It consists of the trnL gene, a group I intron, and the trnL-F intergenic spacer. We analyzed the evolution of the region in three gymnosperm families, Taxaceae, Cephalotaxaceae, and Podocarpaceae, with especially dense sampling in Taxaceae and Cephalotaxaceae, for which we sequenced 43 accessions, representing all species. The trnL intron has a conserved secondary structure and contains elements that are homologous across land plants, and the spacer is highly variable in length and composition. The spatial distribution of nucleotide diversity along the trnL-F region suggests that different portions of this region have different evolutionary patterns. Tandem repeats that form stem–loop structures were detected in both the trnL intron and the trnL-F spacer, and the spacer sequences contain promoter elements for the trnF gene. The presence of promoters and stem–loop structures in the trnL-F spacer and high sequence variation in this region suggest that trnL and trnF are independently transcribed. Stem–loop regions P6, P8, and P9 of the trnL intron and the trnL-F spacer (except the promoter elements) might undergo neutral evolution with respect to their escape from functional constraints.     

红豆杉科及相关类群rbcL基因PCR—RFLP分析

运用RFLP方法对红豆杉科及相关类群14种植物叶绿体rbcL基因PCR产物进行限制酶酶切分析,共获29个酶切变异位点。采用PHYLIP软件包对限制位点变异数据进行极大简约法分析得到18个步长为6的最简约树并求得一致树,结果显示：⑴红豆杉科和三尖杉科属单系群;⑵穗花杉属Amentotaxus以置于红豆杉科内为宜,不支持将穗花杉属独立成科的处理方式;⑶白豆杉应为红豆杉科内一个属Pseudotaxus;⑷三尖杉属内篦子三尖杉地位特殊,可设篦子三尖杉组;⑸不赞同将竹柏类从罗汉松属中分离出去成立新科;⑹红豆杉科、三尖杉科和罗汉松科三者间,前两者的关系更为接近。     

Phylogeny of taxaceae and cephalotaxaceae genera inferred from chloroplast matK gene and nuclear rDNA ITS region

Phylogeny of the Taxaceae genera and the monotypic family Cephalotaxaceae has been extraordinarily controversial. In this paper chloroplast matK genes and nuclear ITS sequences were determined for all six genera of the two families and representatives of other conifer families. Analysis using either the nonsynonymous sites or the deduced amino acid sequences of matK genes strongly indicates that taxad genera and Cephalotaxaceae are monophyletic, with the Taxodiaceae/Cupressaceae clade as their sister group. Cephalotaxus is basal to the taxad genera, among which two clades, Torreya/Amentotaxus and Taxus/Pseudotaxus/Austrotaxus, are resolved. They correspond to Janchen's two tribes, Torreyeae and Taxeae. In Taxeae, Austrotaxus is the first to branch off. Analyses of the nuclear ITS sequence data corroborated the topology of the matK gene tree. These results refute the views that Cephalotaxaceae has no alliance with Taxaceae and that Austrotaxus and Amentotaxus should be excluded from the Taxaceae. We estimated the divergence time between the Taxodiaceae/Cupressaceae and the Cephalotaxaceae/Taxaceae clades to be 192-230 Myr ago and the divergence time between taxads and Cephalotaxus to be 149-179 Myr ago. Soon after the latter divergence event, within 6-8 Myr, the two taxad tribes originated. In conclusion, our data do not support Florin's claim that taxads could be traced to Devonian psilophytes (359-395 Myr ago).     

Molecular phytogeny of conifers using RFLP analysis of PCR-amplified specific chloroplast genes

We investigated the molecular phylogeny of conifers using restriction endonuclease fragment length polymorphism of six polymerase chain reaction-amplified chloroplast genes — frxC, rbcL, psbA, psbD, trnK, and 16S. We detected 227 total site changes among species, representing 23, 26, 38, 48, 67, and 25 site changes in frxC, psbA, psbD, rbcL, trnK and 16S, respectively. The mean nucleotide substitution was 10.75% (SD 0.573) among species in five families. Forty maximally parsimonious trees were obtained using the Wagner parsimony method, and a 50% majority-rule consensus tree was obtained from them. Data analysis produced similar basic patterns when both the Wagner parsimony and the neighbor-joining methods were applied, and the main lineages were clearly separated. Taxaceae and Cephalotaxaceae species were used as the out-groups when applying Wagner parsimony methods. With the Wagner method, the consistency index was 0.510, the retention index was 0.879, and tree length was 435 steps. Our results indicated that Cupressaceae and Taxodiaceae are closely related families and that Sciadopitys verticillata is the basal lineage of Cupressaceae and Taxodiaceae. The neighbor-joining tree is similar to the 50% majority-rule consensus of the 40 Wagner parsimony trees except for the position of Keteleeria daversifolia, the Picea and Cedrus group, and the divergence within Cupressaceae.