Research Article |
Corresponding author: Stuart D. Desjardins ( stuart.desjardins@gmail.com ) Academic editor: Bo Li
© 2023 Stuart D. Desjardins, John P. Bailey, Baowei Zhang, Kai Zhao, Trude Schwarzacher.
This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Citation:
Desjardins SD, Bailey JP, Zhang B, Zhao K, Schwarzacher T (2023) New insights into the phylogenetic relationships of Japanese knotweed (Reynoutria japonica) and allied taxa in subtribe Reynoutriinae (Polygonaceae). PhytoKeys 220: 83-108. https://doi.org/10.3897/phytokeys.220.96922
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Japanese knotweed (Reynoutria japonica) is native to East Asia, but has been introduced to the West where it is a noxious invasive weed. Taxonomically, Japanese knotweed is placed within subtribe Reynoutriinae (Polygonaceae), which also contains the austral genus Muehlenbeckia (incl. Homalocladium) and north temperate Fallopia. In the current study, we conducted a phylogenetic analysis using sequence data from six markers, two nuclear (LEAFYi2, ITS) and four plastid (matK, rbcL, rps16-trnK and trnL-trnF) to further resolve the evolutionary relationships within this group, using the widest sampling of in-group taxa to date. The results of this analysis confirmed that subtribe Reynoutriinae is a monophyletic group, characterised by the presence of extra-floral, nectariferous glands at the base of leaf petioles. Within the subtribe, four main clades were identified: Reynoutria, Fallopia sect. Parogonum, Fallopia s.s. (including Fallopia sects. Fallopia and Sarmentosae) and Muehlenbeckia. The Fallopia s.s. and Muehlenbeckia clades are sister to one another, while the Fallopia sect. Parogonum clade is immediately basal to them and Reynoutria basal to all three. Fallopia, as currently circumscribed, is paraphyletic as Muehlenbeckia is nested within it. To resolve this, we propose that species of Fallopia sect. Parogonum should be treated as a new genus, Parogonum (Haraldson) Desjardins & J.P.Bailey, gen. et stat. nov. Within Reynoutria, the allied specific and infraspecific taxa that fall under the name Japanese knotweed s.l. form a monophyletic group and their taxonomic status is discussed.
Fallopia, invasive aliens, Muehlenbeckia, phylogeny, polyploidy
Japanese knotweed sensu lato is a group of large rhizomatous herbs in the genus Reynoutria Houtt. (
Within the Polygonaceae, Japanese knotweed s.l. is placed in subtribe Reynoutriinae (
Fallopia and Reynoutria have been treated as a single entity ever since
Taxonomic treatment of Fallopia, Muehlenbeckia, Parogonum and Reynoutria in previous classifications.
Fallopia | Muehlenbeckia | Parogonum | Reynoutria | |
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Polygonum sect. Tiniaria | Muehlenbeckia | Polygonum sect. Tiniaria | Polygonum sect. Tiniaria |
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Polygonum sect. Tiniaria | Muehlenbeckia | n/a | Polygonum sect. Pleuropterus |
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Bilderdykia | n/a | n/a | Reynoutria |
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Tiniaria | n/a | Tiniaria | Tiniaria |
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Bilderdykia | n/a | n/a | Reynoutria |
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Reynoutria | n/a | Reynoutria | Reynoutria |
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Fallopia | n/a | Fallopia | Reynoutria |
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Fallopia sect. Fallopia ; sect. Pleuropterus | Muehlenbeckia | Fallopia sect. Parogonum | Reynoutria; Fallopia sect. Pleuropterus |
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Fallopia sect. Fallopia ; sect. Sarmentosae | n/a | n/a | Fallopia sect. Reynoutria ; sect. Sarmentosae |
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Fallopia sect. Fallopia ; sect. Sarmentosae | n/a | Fallopia sect. Parogonum | Fallopia sect. Reynoutria ; sect. Sarmentosae |
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Fallopia | Muehlenbeckia | Fallopia sect. Parogonum | Reynoutria |
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Fallopia | Muehlenbeckia | n/a | Reynoutria |
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Fallopia | Muehlenbeckia | n/a | Reynoutria |
Proposed classification | Fallopia sect. Fallopia ; sect. Sarmentosae | Muehlenbeckia | Parogonum | Reynoutria |
The latest molecular phylogenetic schemes, using plastid and nuclear sequence data, place Reynoutria, Muehlenbeckia and Fallopia in a strongly supported monophyletic group, known as the RMF clade (
Reynoutria is an East Asian genus (
Reynoutria was formerly amalgamated under Fallopia by
Species of Reynoutria are herbaceous, rhizomatous perennials with dry, winged mature perianths, paniculate inflorescences, fimbriate stigmas and are functionally gynodioecious or hermaphrodite (
Reynoutria japonica s.l. is also comprised of a number of infraspecific and allied specific taxa. These include the tall, lowland form var. japonica (= R. japonica s.s.) and the dwarf, montane form var. compacta (= R. compacta), as well as East Asian endemics, such as var. uzenensis Honda (= R. uzenensis (Honda) Honda), var. terminalis (Honda) Kitag., R. elliptica (Koidz.) Migo ex Nakai and R. forbesii (Hance) T.Yamaz (
Fallopia is a heterogeneous genus divided into three sections: sect. Fallopia, sect. Sarmentosae and sect. Parogonum Haraldson (
Fallopia sect. Fallopia was erected by
An examination of secondary chemistry found that the flavonoid profiles of sect. Fallopia form a distinct group, which provides additional evidence for the segregation of sect. Fallopia within the genus (
Fallopia sect. Sarmentosae was erected by
An examination of secondary chemistry found that the flavonoid profile of F. baldschuanica was distinct from other Fallopia species (
Fallopia koreana B.U.Oh & J.G.Kim is a climbing perennial herb endemic to Korea. It is rhizomatous, has enlarged winged perianths in fruit that become twisted at the apex and capitate stigmas with projected surfaces (
Fallopia sect. Parogonum was erected by
A molecular phylogenetic study including F. ciliinodis presented an unclear picture of its position within tribe Polygoneae (
Muehlenbeckia was erected by
The taxa of Muehlenbeckia are variable in habit, ranging from prostrate, mat-forming creepers to erect shrubs to woody lianas; all are perennial and none is herbaceous. Muehlenbeckia species have succulent mature perianths, as opposed to dry and winged as in Fallopia and Reynoutria, fasciculate to racemose to paniculate inflorescences, fimbriate stigmas and are often dioecious (
In the current study, we further resolved the evolutionary relationships of Reynoutria, Fallopia and Muehlenbeckia within subtribe Reynoutriinae by including the widest sampling of ingroup taxa for the clade to date, in particular being the first to include infraspecific taxa and allies of R. japonica, as well as both taxa of Fallopia sect. Parogonum. A phylogenetic analysis was conducted on sequence data from six markers: two nuclear, the second intron of LEAFY (LEAFYi2) and the internal transcribed spacer (ITS) of the 17S-5.8S-26S rDNA region; and four plastid, matK, rbcL, rps16-trnK and trnL-trnF.
An accession list for the current study is presented in Suppl. material
The accessions, collected for the current study, represent the widest sampling of in-group taxa for any phylogenetic study in this subtribe to date (cf.
Total genomic DNA was isolated from dried leaf material using the DNeasy Plant Mini Kit (Qiagen). Six markers, four plastid: matK, rbcL, rps16-trnK and trnL-trnF and two nuclear: ITS and LEAFYi2, were amplified by PCR. The primer sequences and cycling conditions are presented in Suppl. material
Generated sequence reads were viewed, trimmed and edited with Geneious R7 (created by Biomatters; available from http://www.geneious.com/). The sequences were then blasted against the NCBI GenBank database to ensure taxon and gene matches. In total, 259 sequences were used, 107 (41%) of these were newly generated for the current study and 152 (59%) were downloaded from the NCBI GenBank database (Suppl. material
Multiple sequences were aligned for each gene region using the Clustal W algorithm (
Dataset | Aligned length (bp) | No. (%) conserved characters | No. (%) variable characters | No. (%) parsimony informative characters | No. (%) of missing species |
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matK | 1224 | 893 (73) | 331 (27) | 188 (15) | 2 (4) |
rbcL | 1327 | 1140 (86) | 182 (14) | 105 (8) | 15 (28) |
rps16-trnK | 1034 | 729 (71) | 305 (29) | 137 (13) | 20 (37) |
trnL-trnF | 935 | 643 (69) | 292 (31) | 155 (16) | 6 (11) |
ITS | 767 | 465 (61) | 302 (39) | 199 (26) | 3 (6) |
LEAFYi2 | 930 | 541 (58) | 389 (42) | 174 (19) | 22 (40) |
cp combined | 4510 | 3403 (76) | 1107 (24) | 584 (13) | 0 (0) |
Total combined | 6207 | 4420 (71) | 1787 (29) | 951 (15) | – |
Two methods were used to infer the evolutionary relationships of the taxa from the datasets, Maximum Likelihood (ML) and Maximum Parsimony (MP). ML analysis was conducted using PhyML 3.0 (
All sequences generated for this study have been deposited on GenBank (NCBI). Sequence alignments are available in the Suppl. materials
Phylogenetic trees were generated by ML and MP. The two analyses were largely congruent, although bootstrap support (BS) values for ML were generally higher. The trees presented (Fig.
A total evidence phylogenetic tree generated by a Maximum Likelihood analysis of concatenated nuclear (ITS and LEAFYi2) and chloroplast (matK, rbcL, rps16-trnK and trnL-trnF) sequence data. Bootstrap support values (≥ 50%) are displayed above and below the nodes for Maximum Likelihood and Maximum Parsimony analyses, respectively. Maximum Parsimony analysis recovered eight equally parsimonious trees (3099 steps). The main clades within subtribe Reynoutriinae are marked with bars.
The ITS, LEAFYi2 and combined chloroplast (matK, rbcL, rps16-trnK and trnL-trnF) datasets were analysed separately (Suppl. material
The results of the total evidence analysis gave greater resolution and a higher number of strongly-supported nodes than the individual nuclear and combined chloroplast trees alone. In our view, the total evidence tree is the best estimate of the phylogenetic relationships in this study; hereafter, this is the tree described (unless otherwise stated) and forms the basis of our discussions.
Subtribe Reynoutriinae formed a well-supported (93% BS) clade within the Polygonaceae; sister to a subtribe Polygoninae clade (100% BS). Within subtribe Reynoutriinae, there were four well-supported subclades: A) a Reynoutria clade (77% BS with R. multiflora and 99% BS without); B) a Fallopia sect. Parogonum clade (100% BS); C) a Fallopia s.s. clade (100% BS) and D) a Muehlenbeckia clade (100% BS). The Fallopia s.s. and Muehlenbeckia clades were sister to one another with the Fallopia sect. Parogonum clade immediately basal to them (100% BS) and the Reynoutria clade basal to all three (55% BS).
The Reynoutria clade contained R. multiflora, R. ciliinervis, R. sachalinensis, R. japonica var. compacta, R. elliptica, R. forbesii, R. japonica var. terminalis, R. japonica var. uzenensis and R. japonica var. japonica. Within the clade, the erect Reynoutria taxa formed a strongly-supported subclade (100% BS), with R. ciliinervis (99% BS) and R. multiflora (77% BS) as independent basal lineages. However, relationships within the erect subclade were poorly resolved with only weakly-supported internal nodes. Nevertheless, there were two clear subclades within it, a strongly-supported one containing R. elliptica + R. forbesii (94% BS) and a moderately-supported one containing R. japonica var. terminalis, R. japonica var. japonica + R. japonica var. uzenensis (71% BS).
The Fallopia sect. Parogonum clade contained the sister taxa F. cynanchoides and F. ciliinodis with strong support (100% BS). The Fallopia s.s. clade contained two strongly-supported subclades, C1) a sect. Fallopia clade (100% BS) and C2) a sect. Sarmentosae clade (100% BS). The sect. Fallopia clade contained F. convolvulus, F. dentatoalata, F. dumetorum, F. cristata and F. scandens. All relationships within the clade there were strongly supported. Within this clade, F. cristata and F. scandens were almost identical (> 99.85% pairwise identity for all available sequence data) and were placed as sister taxa (100% BS). The sect. Sarmentosae clade contained the sister taxa F. baldschuanica and F. aubertii with strong support (100% BS).
The Muehlenbeckia clade contained three subclades with moderate to strong support, although the relationships between them were entirely unresolved: D1) a Central/South American clade (100% BS); D2) an Australian clade (64% BS) and D3) a predominantly New Zealand clade (86% BS). The American clade contained M. tiliifolia, M. tamnifolia, M. volcanica and M. urubambensis. All relationships within the clade were strongly supported. Within this clade, there were two pairs of sister taxa, M. tiliifolia + M. tamnifolia (99% BS) and M. volcanica + M. urubambensis (77% BS). The Australian clade contained M. gracillima, M. costata, M. gunnii, M. arnhemica, M. zippelii, M. diclina and M. rhyticarya. All relationships within the clade were moderately/strongly supported. Within this clade, there were two subclades, one containing M. gracillima, M. costata and M. gunnii (70% BS) and another containing M. zippelii, M. arnhemica, M. diclina and M. rhyticarya (74% BS). The predominantly New Zealand clade contained M. australis, M. ephedroides, M. astonii, M. complexa, M. axillaris, as well as the Australian endemic M. tuggeranong. All relationships within the clade were moderately/strongly supported. In this clade, there were two subclades, one containing M. australis + M. ephedroides (97% BS) and another containing M. astonii, M. complexa, M. axillaris + M. tuggeranong (58% BS). Within this second subclade, M. axillaris and M. tuggeranong were sister taxa with strong support (100% BS). The placement of M. platyclada and M. adpressa within the genus was unresolved.
LEAFYi2 was single-copy in all diploid taxa and was sequenced directly, but in two polyploid taxa, R. japonica var. japonica and F. convolvulus, two amplicons of different size were observed and these were sequenced from clones (Suppl. material
The species of Reynoutriinae form a strongly-supported monophyletic clade within the Polygonaceae. This clade is characterised by the presence of extra-floral nectaries at the base of leaf petioles (
Reynoutria taxa form a strongly-supported monophyletic clade within subtribe Reynoutriinae, which confirms the findings of previous molecular studies (e.g.
Within the Reynoutria clade, the erect taxa form a strongly-supported subclade (100% BS). Indeed, previous authors (e.g.
Within the erect Reynoutria clade, R. japonica and its allies form a weakly-supported monophyletic subclade, with R. sachalinensis as sister. Within this subclade, the notorious invasive alien var. japonica is most closely related to the other tall lowland forms from Japan, var. uzenensis and var. terminalis, which most likely represent subspecies of R. japonica.
Reynoutria forbesii from China and R. elliptica from Korea are sister taxa and form a monophyletic group, which comes out as sister to R. japonica with weak support. Furthermore, R. forbesii and R. elliptica are very similar morphologically and they most likely represent a single taxon - the epithet forbesii is the older name has priority (
The placement of the high-altitude dwarf form R. japonica var. compacta differed between the individual nuclear and combined chloroplast analyses, being sister to R. sachalinensis on the chloroplast tree (as also demonstrated by
Fallopia ciliinodis and F. cynanchoides form a strongly-supported monophyletic clade within subtribe Reynoutriinae, characterised by papillate trichomes (
The position of Fallopia sect. Parogonum within subtribe Reynoutriinae has been the subject of some speculation.
The species of Fallopia sect. Parogonum, formed a strongly-supported monophyletic clade within subtribe Reynoutriinae and are characterised within the subtribe by capitate stigmas. Within the Fallopia s.s. clade, there are two strongly-supported subclades, corresponding to Fallopia sect. Fallopia and Fallopia sect. Sarmentosae, which are sister to one another.
The species of sect. Fallopia form a strongly-supported subclade within the Fallopia s.s. clade, which confirms the results of previous molecular studies (
The analysis also indicated that F. cristata is not specifically distinct from F. scandens. The phylogenetic analysis placed them as sister to one another and they were almost identical for the markers analysed. The two taxa are thought to be separable on the basis of their mature perianths, which are said to be smaller and more narrowly winged in F. cristata (
The species of sect. Sarmentosae form a strongly-supported subclade within the Fallopia s.s. clade, which supports
The species of Muehlenbeckia sampled formed a strongly-supported monophyletic clade within subtribe Reynoutriinae, which confirms the results of
The placement of Muehlenbeckia taxa in the current study is largely congruent with that of
The placement of M. ephedroides was incongruent between the chloroplast and individual nuclear analyses. In the chloroplast analyses, M. ephedroides fell within a clade with M. axillaris and M. tuggeranong, while in the nuclear analyses, it was sister to M. australis. As is the case in R. japonica var. compacta, M. ephedroides likely has a reticulate history and, during its formation, appears to have captured the haplotype of an ancestor of M. axillaris/M. tuggeranong. This scenario is supported by observations of modern hybridisation in New Zealand Muehlenbeckia (
Reynoutriinae, or the RMF clade, is monophyletic and contains three genera Reynoutria, Muehlenbeckia and Fallopia. However, as currently circumscribed, Fallopia is paraphyletic as Muehlenbeckia is nested between Fallopia sect. Parogonum and the rest of the genus. The subtribe, therefore, requires an immediate taxonomic revision. There are two possible systematic interpretations to restore monophyly in this group, either treat Fallopia, Muehlenbeckia and Reynoutria as a single genus, Fallopia, which has priority, or treat Fallopia sect. Parogonum as a genus in its own right.
Both an amalgamated and a divided Fallopia can be supported by the available molecular data and there are putative synapomorphies for both treatments. An amalgamated Fallopia would include all members of the RMF clade and would be characterised by the presence of extra-floral pit nectaries at the base of leaf petioles and the Tiniaria pollen type (
The two alternative treatments of the subtribe are both perfectly tenable and there are arguments for and against amalgamation. The arguments for amalgamating the genera are threefold: 1) The morphological characters used to separate Fallopia, Muehlenbeckia and Reynoutria are rather inconsistent.
Meanwhile, the arguments against amalgamating the genera are fivefold: 1) Muehlenbeckia has been treated as a distinct entity since its formation, while Fallopia and Reynoutria have often been treated as separate genera (
On balance, we are of the opinion that, despite compelling arguments in favour of amalgamation, species of subtribe Reynoutriinae are better treated as multiple genera to limit nomenclatural upheaval, preserve names in widespread use and to better distinguish the clades. Fallopia sect. Parogonum has, therefore, been treated as a genus in its own right and the relevant binomial changes have been made below.
Fallopia convolvulus (Fallopia sect. Fallopia) is tetraploid (2n = 40), but it is not known if it arose by autopolyploidy or allopolyploidy (
However, this conclusion is not wholly supported by the other available datasets. In the combined chloroplast analysis F. convolvulus was placed basal to the rest of sect. Fallopia and was not sister to F. dumetorum or F. scandens/F. cristata. Furthermore, in the ITS analysis, only one functional copy was detected in F. convolvulus, but this is not unexpected given the homogenising processes of concerted evolution in tandemly-arranged repetitive DNA, such as the ITS (
Subtribe Reynoutriinae is a monophyletic group, which is characterised by the presence of extra-floral, nectariferous glands at the base of leaf petioles. Within the subtribe, four main clades were identified, which represent separate genera: East Asian Reynoutria, disjunct East Asian/Eastern North American Parogonum (Haraldson) Desjardins & J.P.Bailey, gen. et stat. nov., north temperate Fallopia and austral Muehlenbeckia. Within the subtribe, Reynoutria can be identified by the presence of rhizomes, Parogonum by stiff papillate hairs, Fallopia by capitate stigmas and Muehlenbeckia by succulent mature perianths.
Fallopia sect. Parogonum Haraldson, Symb. Bot. Upsal. 22: 78 (1978). Basionym.
Polygonum ciliinode (‘cilinode’) Michx., Fl. Bor.-Amer. (Michaux) 1: 241 (1803). Basionym.
Tiniaria ciliinodis (‘cilinodis’) (Michx.) Small, Fl. S.E. U.S. [Small].: 382 (1903). Bilderdykia ciliinodis (‘cilinodis’) (Michx.) Greene, Leafl. Bot. Observ. Crit. 1: 23 (1904). Reynoutria ciliinodis (‘cilinodis’) (Michx.) Shinners, Sida 3: 117 (1967). Fallopia ciliinodis (‘cilinodis’) (Michx.) Holub, Folia Geobot. Phytotax. 6: 176 (1970). Homotypic synonyms.
Polygonum cynanchoides Hemsl., J. Linn. Soc., Bot. 26: 338 (1891). Basionym.
Fallopia cynanchoides (Hemsl.) Haraldson, Symb. Bot. Upsal. 22: 78 (1978). Homotypic synonym.
Polygonum cynanchoides var. glabriusculum A.J.Li, F. Xizang 1: 608 (1983). Basionym.
Fallopia cynanchoides var. glabriuscula (A.J.Li) A.J.Li, Fl. Reipubl. Popularis Sin. 25: 104 (1998). Homotypic synonym.
Pat Heslop-Harrison and the rest of the Molecular Cytogenetics Lab at the University of Leicester (http://molcyt.com/), where all experiments were undertaken. Special thanks to Peter de Lange (Unitec Institute of Technology, New Zealand) for providing Muehlenbeckia material from New Zealand. We would also like to thank Robert Capers (University of Connecticut, USA), David Boufford (Harvard University Herbaria, USA) and James Armitage (RHS, UK) for providing additional plant material.
A PhD studentship to SDD was funded by a bequest by the late Ann Conolly in partnership with the University of Leicester, UK. Furthermore, SDD’s travel expenses to New Zealand were funded jointly by the Company of Biologists Travel Fund (Society of Experimental Biology) and the Heredity Fieldwork Grant (Genetics Society).
Additional phylogenetic trees from ITS, LEAFYi2 and combined chloroplast analyses.
Data type: pdf file
Explanation note: fig S1. A phylogenetic tree generated by a Maximum Likelihood analysis of ITS sequence data. Bootstrap support values (≥ 50%) are displayed above and below the nodes for Maximum Likelihood and Maximum Parsimony analyses, respectively. Maximum Parsimony analysis recovered two equally parsimonious trees (825 steps); fig S2. A phylogenetic tree generated by a Maximum Likelihood analysis of LEAFYi2 sequence data. Bootstrap support values (≥5 0%) are displayed above and below the nodes for Maximum Likelihood and Maximum Parsimony analyses, respectively. Hyphens (-) indicate nodes where parsimony and likelihood trees differ in branching pattern. Maximum Parsimony analysis recovered three equally parsimonious trees (598 steps); fig S3. A phylogenetic tree generated by a Maximum Likelihood analysis of concatenated chloroplast sequence data (matK, rbcL, trnL-trnF & rps16-trnK). Bootstrap support values (≥ 50%) are displayed above and below the nodes for Maximum Likelihood and Maximum Parsimony analyses, respectively. Maximum Parsimony analysis recovered 191 equally parsimonious trees (1600 steps). The main clades within subtribe Reynoutriinae are marked with bars.
Accessions used in the current study
Data type: excel file
Primer sequences and PCR cycling conditions
Data type: excel file
ITS multiple-sequence alignment
Data type: .txt file
LEAFYi2 multiple-sequence alignment
Data type: .txt file
Combined chloroplast multiple-sequence alignment
Data type: .txt file
Total evidence multiple-sequence alignment
Data type: .txt file