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A revision of Australian Plagiochila (Lophocoleinae: Jungermanniopsida) PDF

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Telopea Volume 21: 187-380 The Royal Publication date: 29 November 2018 Botanic Gardens Journal of Plant Systematics dx.doi.org/10.7751 /telopeal 2959 & Domain Trust plantnet.rbgsyd.nsw.gov.au/Telopea • escholarship.usyd.edu.au/journals/index.php/TEL • ISSN 0312-9764 (Print) • ISSN 2200-4025 (Online) A revision of Australian Plagiochila (Lophocoleinae: Jungermanniopsida) Matt A.M. Renner National Herbarium of New South Wales, Royal Botanic Gardens and Domain Trust, Mrs Macquaries Road, Sydney, NSW2000, Australia. Abstract Fifty-five Plagiochila species are recognized for Australia and New Zealand, of which nine are new, all from Australia with eight of the new species from the Wet Tropics Bioregion of north-east Queensland and the nineth from the south-eastern mesic archipelago of eastern New South Wales and south-east Queensland. Four of the new species belong in the challenging, and neglected, section Vagae. Three new Australian records are reported, P. daviesiana, P monospiris, and P streimannir, and one species, P alta, is a new record for New Zealand. Six species, P annotina, P circumdentata, P colensoi, P deltoidea, P gigantea and P ramosissima, are excluded from Australia as these are all New Zealand endemics reported in error for Australia. Plagiochila haylisii, previously considered a New Zealand endemic, is reported new for Australia. Four species are excluded from Australia, P furcata, P. inflata, P renitens and P sciophila, as they are based on misidentifications or are not supported by voucher material. Another interpretation of the confusion surrounding the name Plagiochila haileyana is presented, wherein Plagiochila baileyana is accepted as a species distinct from P gigantea, while Plagiochila aculeata is returned to synonymy of P fasciculata, and Plagiochila subfasciculata Colenso is reinstated. The number of Plagiochila species in Australia increases from 32 to 41, but the number of species in New Zealand decreases from 28 to 27 as a result of this study. New combinations at species level are also proposed for a variety of P. blepharophora from Fiji and two varieties of P gymnoclada from Sumatra and Java, two species which morphological data suggests are grossly polyphyletic as they are currently circumscribed. Introduction The genus Plagiochila currently contains around 600 accepted species (Soderstrom et al. 2016) globally distributed in mesic environments, including lowland tropical rainforest and alpine herbfields. Different species partition microsites, including rock, soil, decaying wood, tree trunks, branches, and twigs, and within a forest all microsites except leaf surfaces maybe routinely colonized by various Plagiochila species. For example, in tropical montane forest of the Wet Tropics bioregion in Queensland Plagiochila baileyana Steph. occupies saturated humic soil on the forest floor, P conturbata Steph. and P aenea M.A.M.Renner grow on granite boulders, P monospiris Inoue & Grolle grows on decaying wood, P arbuscula (Brid. ex Lehm.) Lindenb. grows on tree trunks, and P queenslandica Steph. and P daviesiana Steph. grow on tree trunks, branches and twigs. On the west coast of the South Island, New Zealand, Plagiochila circumdentata Steph. and P incurvicolla Hook.f & Taylor grow on rocks and sand within and alongside streams, P banksiana grows on damp soil. © 2018 Royal Botanic Gardens and Domain Trust 188 Telopea 21: 187-380, 2018 Renner often on streambanks, P. intertexta Hook.f. Sc Taylor may inhabit damp rocks, P gigantea Lindenb. grows in depressions on the forest floor, P stephensoniana Mitt, and P trispicata Colenso, grow around tree trunk bases, P annotina Lindenb., P. incurvicolla, and P strombifolia Mitt, grow on tree trunks, and P circinalis Lindenb. grows on branches and twigs. In some situations, including the tree trunks in the previous example, several species may co-occur within the same microsite. In lowland tropical rainforests in the Queensland Wet Tropics three species, P daviesiana Steph., P teysmannii Sande Lac., and P bantamensis (Reinw, Blume et Nees) Mont, can be found syntopic on twigs and branches within riparian forest. Species packing within and partitioning among microsites combine with the wide range of microsites and climatic breadth occupied resulting in high Plagiochila species diversity, both within the Australasian region and elsewhere. The first Plagiochila collections from Australasia were made by Archibald Menzies (1754-1842) at Dusky Bay in Fiordland, New Zealand during his appointment as naturalist on the global voyage of HMS Discovery under Captain George Vancouver. Menzies collected at least four Plagiochila species at Dusky Bay (now Dusky Sound). Three of these, Plagiochila annotina, P. gigantea, and P ramosissima were described by William Jackson Hooker (1818) on the basis of his gatherings and have the distinction of being the first Plagiochila reported from New Zealand and Australia. New species were still being described from Menzies specimens more than fifty years after their collection, when Lindenberg (1843) described Plagiochila deltoidea Lindenb. and included a Menzies gathering in the original material. The next Plagiochila reported from Australasia was Plagiochila circinalis (Lehm. & Lindenb.) Lehm. & Lindenb., (Lehmann 1832) described as a species of the portmanteau genus Jungermannia, on the basis of collections by Charles Fraser (c. 1788-1831), first colonial botanist and superintendent of the Botanic Gardens, Sydney, who made trips to Tasmania in 1820 and 1826 (Orchard 1999). The next significant Plagiochila collections from Australia and New Zealand were made during the voyage of HMS Erebus and Terror, which made landings at Lord Auckland’s Island, Campbell Island, Van Diemens Land (Tasmania), and the Bay of Islands in the North Island of New Zealand during their Antarctic Voyage. At these localities, the expeditions botanist Joseph Dalton Hooker collected bryophytes and in Tasmania and New Zealand received bryophytes from local collectors. In Tasmania Hooker received collections made by R.C. Gunn. At the Bay of Islands he received collections made by the Reverend William Colenso, who had travelled from Hawke’s Bay to meet with Hooker. The Bay of Islands in the early 1840s proved an important locus that would set the course of New Zealand bryology for the next four decades. In addition to HMS Erebus and Terror, HMS Eavorite, with Dr Andrew Sinclair (1794-1861) aboard as surgeon, visited the Bay of Islands in 1841. Here Sinclair met with the younger Hooker, who was aboard HMS Erebus as assistant surgeon. Dr David Lyall (1817-1895), aboard HMS Terror as surgeon, and the Rev. William Colenso Esq. Together these four collected around the Bay of Islands. Given the subsequent contribution of specimens each gentleman made toward Hooker’s Flora of New Zealand, it is possible that they all discussed Hooker’s plans for the completion of that project. The specimens assembled by Hooker from the Antarctic Voyage were studied by Thomas Taylor, who co-authored 10 new Plagiochila species from New Zealand and Tasmania with Hooker (Hooker and Taylor 1844a, 1844b). Dr Lyall went on to serve as surgeon aboard the paddle sloop HMS Acheron between 1848 and 1851 and with her was dispatched for a coastal survey of New Zealand, an appointment that facilitated collections from around New Zealand; while Sinclair became Colonial Secretary of New Zealand under Governor FitzRoy at Auckland. Colenso, Lyall, and Sinclair all continued to collect bryophytes, sending their specimens to Hooker, who in turn sent material to William Mitten, author of the bryophyte sections following the death of Taylor in 1848. The association between these four botanists was commemorated in the dedication of Hooker’s Flora of New Zealand (Hooker 1855), and in species described by Mitten. Two new Plagiochila species described by Mitten honoured Hooker’s colonial collectors, P sinclairii Mitt., and P stephensoniana Mitt., the latter named for W. Stephenson (c. 1810-c. 1863) who gathered material in the Wellington region. Subsequently, and following the publication of Hooker’s Flora, Colenso began describing new Plagiochila species based on his own gatherings, mostly made in the North Island (Colenso 1887,1888), and he has the distinction of being the first New Zealand resident botanist to describe new New Zealand liverworts. Other early collections of Plagiochila were opportunistic, some occurring within circumstances of historical significance. One notable, perhaps notorious, example is provided by a specimen of Plagiochila kirkii Mitt, ex Steph. gathered by Captain Sir James Evarard Home 2""^ Bart. C.B. (1798-1853) of HMS North Star, 26 guns, from Kerikeri Falls in October 1845, during the ship’s deployment in the ‘Flagstaff War’—the first conflict of the New Zealand Wars. HMS North Star left the Bay of Islands for England on 11 January 1846 and arrived home, with its specimens, on 19 December 1846. This sizeable specimen, a rectangle of bark neatly cut from a tree probably with a small tomahawk, now resides in the Natural History Museum, London. A revision of Australian Plagiochila (Lophocoleinae: Jungermanniopsida) Telopea 21: 187-380, 2018 189 Mittens treatment in Hookers Flora of New Zealand (Hooker 1855) recognized 18 Plagiochila species, some of which are now attributed to other genera including Dinckleria Trev. and Chiastocaulon Carl within the Plagiochilaceae (Groth and Heinrichs 2003; Patzak et al. 2016), but also to Calyptrocolea within the Adelanthaceae. Mitten described six new species, four of which are accepted today. During the early phase of European settlement of Australia and New Zealand, resident botanists either volunteered themselves or were appointed to make known the botany of their new colonies. These botanists sent a mixture of their own and others collections back to the northern hemisphere, where active bryologists resided. Australia’s first government botanist, Alan Cunningham (1791-1839) travelled to Australia in 1816, and participated in several collecting expeditions between 1818 and 1831. Cunningham’s collection focus was vascular plants, but he did collect non-vascular plants on Lord Howe Island and New Zealand. Other resident botanists who collect or communicated significant collections of non-vascular plants in the mid- to late 19* Century included Ferdinand von Mueller (1825-1896), government botanist in Victoria who was appointed in 1853, Thomas Kirk (1828-1898) in New Zealand who in 1868 became Curator at Auckland Museum, and Fredrick Manson Bailey (1827-1915) the first government botanist for the state of Queensland, commencing that position in 1881. Notable among Bailey’s collections are those from Bellenden Ker, made during an expedition to the summit in 1889. The 1889 Government Scientific Expedition to the Bellenden Ker Range expedition was led by Archibald Meston and included EM. Bailey (Dowe and Broughton 2007). They established a base camp on the Mulgrave Plain and explored the Mulgrave River, Harvey Creek, and Russell River areas, including an ascent of Mt Bellenden Ker returning via the Mulgrave River (Dowe and Broughton 2007). The ascent and descent of Bellenden Ker took more than a month, 15 June to 17 July (Dowe and Broughton 2007). In Tasmania, William Anderson Weymouth (1841-1928) and Leonard Rodway (1853-1936) both sent specimens to Europe, as did Isaac Robinson from Norfolk Island. Thomas Wrench Naylor Beckett (1839- 1906), who had settled in Christchurch, collected from along the eastern side of the main divide and up and over Arthur’s Pass onto the West Coast—along with Berggren in 1874-75 the first bryologists to collect along this route, from New Zealand. The most significant collector and correspondent of this period though, was probably The Reverend William Walter Watts (1856-1920), who had arrived in Australia from England in 1887. For six years he was minister in Ballina, northern NSW, before moving to Young and Gladesville. Watts made prolific collections of mosses and liverworts, particularly around the Richmond River, and exchanged specimens with Brotherus and Stephani (Ramsay 1980). On Watts’ death the NSW herbarium purchased his complete herbarium (Ramsay 1980). The resulting specimen flow fueled the description of many new species, particularly when Franz Stephani (1842-1927) took it upon himself to fill the gap in expertise left by the deaths of Thomas Taylor (1775-1848), J.B.W. Lindenberg (1781-1851), C.G.D. Nees von Esenbeck (1776-1858), C.M. Gottsche (1808-1892), and the aging William Mitten (1819-1906). Stephani was, for a time, the world’s foremost authority on liverworts and viewed literally tens of thousands of specimens during the preparation of his Species Hepaticarum, including many from Australia and New Zealand. Stephani even saw duplicates of many of the specimens Colenso had sent to Hooker at Kew, and was not averse to describing new species based upon them. Stephani was a prodigious describer of new species and published no less than 22 new Plagiochila species from Australia and New Zealand in his Species Hepaticarum from specimens sent to him from Tasmania and New Zealand, including P beckettiana Steph., (Colenso, Beckett), P circumdentata (Beckett), P kirkii Mitt, ex Steph. (Kirk), P taylorii Steph. (Weymouth), and P decurvifolia Steph. (Weymouth). Despite being sometimes maligned for having ‘taxonomic capacities too limited for the job’ (Gradstein 2006 p. 560) Stephani could be a careful observer and did recognize as new many species we accept today. Although it could be argued that this was an artifact of being an early player on the board, in which circumstance even an entirely haphazard approach to species description would identify genuinely new species, Stephani’s work is generally more nuanced than this. There is also an element of bias against Stephani stemming from the modern trend toward application of species concepts that are inappropriately broad. Indeed, in this revision of Australian Plagiochila, five of Stephani’s species are reinstated from synonymy where they have languished due to subsequent misinterpretation of species circumscriptions or type specimens. To some extent, contemporary criticism of Stephani reflects our own failings as much as it identifies his. The first regional treatment dedicated to Plagiochila was completed for the New Zealand species by Eliza Amy Hodgson (1888-1983), a remarkable woman who, with limited resources but much dedication, published a series of treatments for some of the larger and more challenging New Zealand liverwort genera, some of which remained current into the 2T* century. Hodgson began her revision of Plagiochila by outlining the recognised difficulties inherent in species circumscription, including their being ‘difficult of recognition and puzzling to identify’ and‘difficult to define species limits’ (Hodgson 1944 p. 270). Hodgson recognized 25 species in New Zealand, 19 of which are attributable to Plagiochila as currently circumscribed (Hodgson 1944). The only 190 Telopea 21: 187-380, 2018 Renner new taxon described by Hodgson (1944) was Plagiochila gregaria van ovalifolia E.A.Hodgs., treated below as a straight synonym of R gregaria (Hook.f. & Taylor) Gottsche, Lindenb. & Nees. After Hodgsons work, it was nearly 30 years before the next regional revision of Plagiochila was completed, by Inoue and Schuster (1971) who recognized 25 species of Plagiochila for Tasmania and New Zealand including three new species, P caducifolia Inoue & R.M.Schust. P. baylisii Inoue &: R.M.Schust., and P fragmentissima Inoue &: R.M.Schust. The treatment presented by Inoue and Schuster (1971), in its nuanced interpretation of morphological variation and attention to detail with an emphasis on homology, can be regarded as the first modern revision of Plagiochila in the Australasian region. Following on from that work, the second modern revision was presented for species of mainland Australia by Inoue (1986) on the basis of the specimens then available, including recent collections from the Wet Tropics made by Marie Hicks. Inoue (1986) described no new species but did report four species new to Australia and extended the ranges of a number of southern species into the Australian Wet Tropics. Subsequent collecting efforts have identified additional species and helped clarify the circumscription of others treated by Inoue. Indeed, the greatest changes in species composition and circumscription resulting from this revision apply to the flora of the Wet Tropics bioregion, which reflects how well studied this region is. Our knowledge of Plagiochilaceae in the Australian Wet Tropics remains incomplete, and new finds, including new species, should be anticipated as the geographic coverage of future collecting effort becomes more comprehensive, even in recently revised genera, see for example Renner and Worboys (2018). Three new species were described from New Zealand at the end of the 20*^^ Century, Plagiochila hazzanioides J.J.Engel & Merrill from Rangitoto Island (Engel and Merrill 1999); Plagiochila hatcheri J.J.Engel & Merrill from Stewart Island, and P kermadecensis J.J.Engel & Merrill from Raoul Island. Though each of these species is accepted in this revision, all have earlier names, two having already been synonymized (Engel and Merrill 2010) the third, P hazzanioides, is predated by P kirkii Steph. which is reinstated in this treatment. The summation of this work is that 32 species of Plagiochila have been reported for Australia since 1843 and not definitely excluded (Lindenberg 1843; Hooker and Taylor 1844a, 1844b; Bastow 1886; Weymouth 1902; Inoue and Schuster 1971; Inoue 1986; Glenny and Jarman 2008; Engel and Merrill 2010a, 2010b, 2013), around 16 of which are shared with New Zealand. Currently 28 Plagiochila species are recognized for New Zealand (Engel and Merrill 2009,2010a, 2010b, 2013; de Lange et al 2014), not including Cryptoplagiochila radiculosa (Mitt.) S.D.EPatzak, M.A.M.Renner &: Heinrichs (Patzak et al. 2016). Species circumscription, identity, and nomenclatural priority have been the subject of recent taxonomic research in preparation for the third volume of the Liverwort Flora of New Zealand series (Engel and Glenny 2008), and this effort has resolved many areas of persistent confusion, for example surrounding the application of the names Plagiochila retrospectans and P.fuscella (Engel and Merrill 2009), the identity of Plagiochila hatcheri (Engel and Merrill 2010a), and the status of some early but neglected names. This might suggest that the diversity of Plagiochila in New Zealand is more or less completely known, but this is not necessarily the case, as discussion of P deltoidea and P baylisii below demonstrates. The application of names, a problem quite separate from the circumscription of entities to name is, in this study, also the cause of some deliberation. Interpretation of types is often a matter of considerable complexity, with good reason. Stephanis types in Geneva are usually fragmentary, his herbarium having been divided a couple of times prior to its purchase by G, and some specimens now comprise single shoot systems, or fragments thereof. For species whose shoots exhibit hierarchical structuring wherein leaves on primary and secondary shoots differ in size and shape, and differences between species manifest most conspicuously on primary shoots, types that comprise fragments of secondary or tertiary shoots alone may be very difficult, if not impossible, to assign to a known species with confidence. Even types comprising relatively intact shoot systems with tractable hierarchy are difficult to relate to known species within complexes of closely related, morphologically similar and simultaneously variable forms as, for example, in the Plagiochila arbuscula complex (Renner et al 2018). Despite considerable challenges, however, species circumscription, specimen identification, and type-specimen assignment are all possible using morphological data so long as the interpretation of morphology is methodical, nuanced, and coupled to recognition of both variability and hierarchical structuring. Some revisions of Plagiochila for Australia, New Zealand, and the Pacific are not well characterized by these criteria. This revision for Australia seeks to build on the platform laid by the flora research program being completed in New Zealand. Phylogenetic context All studies referred to above are based on morphological data, being completed or started before the inclusion of molecular data in liverwort taxonomic studies became routine. The first study of Plagiochila including molecular data was published by Heinrichs et al (2002), and insight into relationships from that and subsequent A revision of Australian Plagiochila (Lophocoleinae: Jungermanniopsida) Telopea 21: 187-380, 2018 191 molecular phylogenetic investigations has impacted the classification of Plagiochilaceae at all levels. The genera Dinckleria and Chiastocaulon have been reinstated from synonymy with Plagiochila (Groth and Heinrichs 2003; Heinrichs et al 2006; Patzak et al 2016), while Rhodoplagiochila R.M.Schust. was sunk (Heinrichs et al. 2004a). The sectional classification for Plagiochila has been progressively refined as knowledge of phylogenetic relationships gradually emerged from molecular phylogenetic studies (Heinrichs et al 2003, 2004b, 2005a; Renner et al 2017a, 2017b), and recently the sectional classification was overhauled in line with relationships inferred from a global sample of taxa including a near complete sample of Australasian species (Renner et al 2017c). Molecular data have also provided insights informing species circumscription. Heinrichs et al (2003) noted incongruent morphological and molecular divergence, within both closely and distantly related pairs of Plagiochila species. Heinrichs et al (2004c) considered molecular data in their decision to adopt a broad species concept for the morphologically variable P bifaria, and the intercontinental distribution of P corrugata and P punctata (Taylor) Taylor was confirmed using molecular sequence data (Heinrichs et al 2004d, Heinrichs et al 2005b). Revisions of Dinckleria and Chiastocaulon for Australia employed automated species delimitation methods based on genetic distances (Automatic Barcode Gap Detection: ABGD) and tree topology using the General Mean Yule Coalescent (GMYC) estimated from a three marker molecular dataset (Renner et al 2016a, 2016b, 2017a). A revision of the Plagiochila arbuscula complex integrated molecular and morphological data; and used Geometric Morphometric Methods (GMM) to circumscribe differences in patterns of leaf shape variation among lineages within this complex. Differences so identified were then reflected onto type specimens of challenging interpretation to achieve data-based assignment of types, which resulted in the reinstatement of two species (Renner et al 2018). The strong floristic linkages between Australia and New Zealand, particularly between south-east Australia and New Zealand have long been recognized and are reflected in the number of species distributed on both sides of the Tasman Sea (Inoue and Schuster 1971; Inoue 1982). Treating Australia and New Zealand in a single revision is further justified by three factors, firstly the reciprocal exclusion of species currently thought shared by Australia and New Zealand, and contrarily the new Australian records for species thought endemic to New Zealand, both of which result from study of Australian specimens, but which have bearing on the New Zealand flora. Secondly, the species circumscriptions reached in this study on the basis of a synthesis of molecular and morphological data differ for some species from those in the forthcoming Flora of New Zealand treatment, and these differences have implications for species recognized in New Zealand. Finally, there is always the possibility that species currently New Zealand endemics will be detected in Tasmania, and vice versa. For these reasons the floras of Australia and New Zealand are both treated in this work. This revision builds upon the work completed by Inoue and Schuster (1971), Inoue (1986) and Engel and Merrill (2009a, 2010a, 2010b), and recognizes 55 species from Australia and New Zealand. Nine are new species, all from Australia, with eight from the Queensland Wet Tropics Bioregion and one from south-eastern Australia. Four of these new species belong in section Vagae. Three species are new Australian records - P daviesiana, P monospiris, and P streimannii again all from the Wet Tropics; and one species, P alta Steph., is a new record for New Zealand. The concentration of novelties within this Bioregion reflects how little studied this part of Australia is, as was reflected in Inoue s (1982) synopsis of speciation and distribution of Plagiochila in Australasia and the Pacific, at which time only 12 species were recognized from mainland Australia, mostly from the south east. The Australian records for six species --P annotina, P circumdentata, P colensoi, P. deltoidea, P gigantea and P ramosissima—dire rejected, these species become New Zealand endemics as a result; while one other New Zealand endemic is reported new for Australia {P baylisii). Four species are excluded from the Australasian region entirely, Pfurcata, P inflata, P renitens, and P sciophila. Another interpretation of the confusion surrounding the name Plagiochila baileyana sensu Inoue and Schuster (1971) is presented, wherein Plagiochila baileyana is accepted as a species distinct from P gigantea, while Plagiochila aculeata is treated as a synonym of P fasciculata, and Plagiochila subfasciculata Colenso is reinstated to accommodate some of the plants assigned to P baileyana by Inoue and Schuster (1971), and to P aculeata by Engel and Merrill (2010). Arrangement of species is by section, following the sectional circumscription presented by Renner et al (2017c), the sections are ordered by phylogeny, with sect. Denticulatae first, sect. Austrocaules second, and the others following with sect. Vagae presented last. This revision strives for better understanding of phylogenetic and morphological diversity within Plagiochila. It does not strive to provide a final answer in terms of the diversity, distribution, and circumscription of species in Australia, or the names that should be applied to them. Indeed, perhaps the most interesting components of this treatment are the areas of residual uncertainty, about which this treatment seeks explicit disclosure, that future improvement in our understanding might be more readily achieved. Eurther details in areas where species circumscription and the application of names might be improved are described under the species treatments below. Indeed, some significant challenges to species circumscription manifest in this study, some are intrinsic to the plants themselves, others to current circumstances, and it is unlikely that I have overcome 192 Telopea 21: 187-380, 2018 Renner them all. Among intrinsic factors are the hierarchical structuring of shoot morphology, where shoot systems comprise a structured ordinal hierarchy of differentiated shoots that decrease in size with increasing shoot order, and express size-correlated patterns of morphological variation. Many diagnostic differences among species are associated with characters expressed at the larger end of this spectrum of size-correlated variation, in other words, on primary shoots. Type specimens, particularly of species belonging to Plagiochila sect. Vagae may comprise secondary, tertiary and quaternary shoots. It is then exceptionally challenging to relate type specimens with species. The hierarchical structuring of Plagiochila shoot systems seems under-appreciated by previous studies. Published descriptions and illustrations of leaf shape are usually of unknown shoot order, or orders, and species circumscription and identification both suffer because this obscures relevant patterns of structural variation. Inoue and Schuster (1971) sought to incorporate data from new sources into a framework of traditional interpretation, and this served well in the circumscription of species when fresh and fertile material were available. Unfortunately, this approach did not always serve the purposes of effective interpretation of type material, and the identification of sterile, and male or female material in some species, remains challenging as illustrated by the following examples: 1) the synonymisation of P. alta Steph. (sect. Belangerianae) with P teysmannii (sect. Vagae) (So 2000). 2) the synonymisation of P serrifolia with P vitiensis (Inoue 1986) 3) the synonymisation of P multifurcata with P queenslandica (Inoue 1986) 4) the synonymisation of P. queenslandica with P metcalfii (So 2000) 5) application of the name P baileyana Steph. to plants from New Zealand (Inoue & Schuster 1971). This study seeks a novel interpretation of some older taxonomic character systems from the vegetative gametophyte that explicitly acknowledges the existence of hierarchical structuring within shoot systems and overlapping parameters of variation among species in an effort to achieve durable attribution of type material to entities resolved on the basis of morphological and molecular data. For this reason, species circumscriptions rely heavily on characters from the sterile gametophyte, as these are present in all specimens including types. Access to type material has imposed some limitations on this study, and an understanding of how those limitations have influenced my nomenclatural decisions will help future investigations understand why I have recognized new species, reinstated synonyms, or not. My efforts to relate Australian species to relevant type material, involved a two-week visit to Geneva in 2014 to examine as many regional types as possible. I examined many, but really needed to see them all again at this study’s end. Where I am aware of the need to assess my new species with respect of close relatives overseas, I have made this need explicitly clear alongside my justification for the recognition of the new species. In other instances, I reinstate species from synonymy and apply reinstated names to Australian plants because I am more confident of the application of the synonym than the name which may have priority. Plagiochila daviesiana represents an example of this. In this, and indeed in other instances, I suspect it will not be possible to arbitrate over various applications of some names, P. daviesiana versus P junghuhniana among them, until topotype material has been collected and the patterns of morphological variation expressed by that material fully appraised and if needed quantified, and the specimens included in a molecular dataset to place the plants within the Plagiochila phylogeny. Unfortunately, no bona fide specimens of P junghuhniana have yet been included within a molecular phylogeny. The inclusion of well-characterized topotype material in future studies is a pressing need. Finally, the application of names can be impacted by the typification of species. In Volume 1 of his Index Hepaticarum, Bonner (1962) inadvertently lectotypified many Plagiochila species on material held in Geneva, because he identified specimens he regarded as types, in accordance with the code. I thank the late Prof. Dr Jochen Heinrichs for pointing out that many hepaticologists, myself included, have overlooked this fact. Character analysis Shoot system replication Inoue and Schuster (1971) characterized well the difference between leafy shoot systems with determinate vs unlimited growth, and indeed a distinction between these two kinds of shoot architecture can be made when opposing ends of the spectrum of variation in shoot architecture in Plagiochila are compared. At one end of this spectrum are shoot systems expressing a sharp distinction between an erect leafy sector, and a creeping, basal, microphyllous stolon. In these shoot systems the stolon proliferates basally, arising exclusively from other stolons, and never or very rarely are stolons produced de novo by leafy shoots. Leafy shoots always start as stolons, before turning away from the substrate and transitioning to leafy growth, simultaneously A revision of Australian Plagiochila (Lophocoleinae: Jungermanniopsida) Telopea 21: 187-380, 2018 193 producing a new stolon by intercalary branching near the point of upturning. Shoots replicate basally by the production of new stolons. Examples of species with this growth mode include R arbuscula, P. circinalis and R queenslandica, and all species of sect. Vagae have shoot systems that replicate basally. At the other extreme are shoots that replicate apically by producing intercalary branches from within their leafy sectors. These intercalary branches are initially microphyllous and stolon-like but immediately turn upward and transition to leafy growth. Examples of species with this growth mode include R gigantea, R retrospectans, and R lamellata. However, these two growth modes are linked by a range of intermediates that serve to blur any clear distinction between the two. Plagiochila banksiana grows primarily by production of leafy shoots from other leafy shoots. This species does not often express any stolon shoot sectors. The same is true of R intertexta, though this species does often produce short isolated basal stolons amidst its prostrate and proliferating leafy shoots. On the other hand, while Plagiochila minutissima has shoots divided into stolon and leafy sectors, this species may produce stolons de novo just about anywhere, including within leafy and stolon sectors. Shoot growth habit may also differ among species with the same growth mode, for example the shoot systems of Plagiochila gigantea are erect, while those of the outwardly similar R baileyana are procumbent, so that while having the same architecture the appearance of the plants in situ is quite different. Leafy shoot organization Plagiochila species may produce monomorphic leafy shoots, or hierarchically structured leafy shoots wherein different branch orders express differences in stature, with stature decreasing with increasing branch order. The largest shoots are always those arising from the basal stolon, and secondary, tertiary, and even quaternary shoots are always smaller by degrees. Hierarchically structured shoots may be pinnate or bipinnate, as in Plagiochila arbuscula, or dichotomous as in R queenslandica. In sect. Vagae vegetative branching in all species is pseudodichotomous; the branch displaces the leading shoot causing a fork. The symmetry of pseudodichotomy varies among species; in most the fork forms a right angle or close to it but in other species such as R streimannii the displacement of the leading shoot is but slight, and the pseudodichotomy is not immediately apparent, except that the leading shoot alternates left to right more than is quite usual between successive branches. Neither Inoue and Schuster (1971), Inoue (1984), nor So (2000) explicitly noted hierarchical structure in shoot morphology. Branching Branch types provide significant clues to the identity of plants and different branching modes in stolons and subfloral innovations contribute to circumscribing some of the major lineages within Plagiochila. There is a structural component to branch production that is a function of shoot system organization, and this is a critical component in the interpretation of branching type that has not been fully appreciated. Branching within stolon sectors and leafy sectors are often by entirely different modes, and within leafy sectors vegetative branching often differs in mode from branching to produce shoots bearing reproductive structures. Within the stolon sector, most Plagiochila species issue new stolons via lateral-intercalary branches. However, two Australasian species, P. deltoidea and P. ratkowskiana, produce ventral-intercalary branches within their stolon sectors. These ventral-intercalary branches appear to originate deep within the stem, possibly in the outer layers of the medulla, as they split the stem cortex longitudinally as they erupt and mature. This difference in the branch type by which new stolons are produced provides a valuable character for differentiating P. deltoidea from species to which it is superficially similar including P. fasciculata, P. hartziana, and P. strombifolia, particularly when material is sterile. Within leafy shoot sectors two vegetative branch types predominate, Frullania-type and lateral-intercalary branching. Some species produce vegetative branches exclusively by one branch type or the other; in P. abietina, P. arbuscula and P. queenslandica for example vegetative branching is exclusively (or nearly so) Frullania-type, whereas in P. lamellata, P. aenea and P. rutlandii it is exclusively lateral-intercalary. Other species including P. fasciculata, P. incurvicolla, and P. hartziana produce both Frullania-type and lateral-intercalary vegetative branches and the relative frequency of each type varies among species, in this example lateral-intercalary vegetative branches are uncommon in P. fasciculata while they predominate in P. incurvicolla. Ventral- intercalary vegetative branching is absent from all Plagiochila species, except when shoot tips are damaged and the apex removed, in which case new vegetative shoots are produced close to the apex by lateral-intercalary branching alone, or a combination of lateral- and ventral-intercalary branching. If a plant produces normal ventral-intercalary vegetative branches, then it belongs to either Dinckleria or the Chiastocaulon lineage. Species whose vegetative branches are otherwise exclusively Frullania-type will produce lateral-intercalary branches in response to apex damage, so the state of the shoot apex should be checked when making an assessment of the vegetative branch types. 194 Telopea 21: 187-380, 2018 Renner Subfloral innovations are borne immediately below the gynoecium in most Plagiochila species, such that exceptions like R abietina are notable. In most Plagiochila species the subfloral innovations issue by lateral- intercalary branching, but in species of sect. Denticulatae the subfloral innovations are produced by ventral- intercalary branching and lateral-intercalary branching. Usually the subfloral branch is ventral-intercalary when one subfloral innovation is present, and lateral-intercalary when two or more are present, but both types may be associated with a single gynoecium. In the male plants of many Plagiochila species male branches are produced in terminal pairs, or fascicles of three or more male branches at the apex of leafy shoots, with branches issuing from the base of the first (leading) male branch producing others. The branch type associated with the proliferation of male branches is usually Frullania-type, such that some species with exclusively lateral-intercalary vegetative branching may produce Frullania-type male branches, and the production of male branches is the only circumstance in which Frullania-type branches are manifest in those species. Plagiochila deltoidea and P ratkowskiana both produce ventral-intercalary branches in association with male branches, either at the branch base or from among the male bracts, and these may proliferate male branches or produce a vegetative branch. Leaf shape Leaf shape varies among species of Plagiochila and presents a critical source of species-circumscribing features despite considerable within-individual and within-species variation. Within individuals leaf shape often expresses variation correlated with size. The breadth of this size-correlated variation within individuals is often greater than the differences in leaf shape expressed among species, and as such ranges of shape and size variation overlap across species and no morphological discontinuity may be evident when leaf shape or size are considered independently. However, in many species of Plagiochila differences in leaf shape and size manifest in the size and shape of the largest leaves associated with primary shoots, which may provide diagnostic, if subtle, differences useful for species circumscription and specimen identification, as demonstrated by Renner et al (2018). Correspondingly, the shape of leaves from secondary, tertiary, and quaternary shoots, tend to be smaller and may not provide diagnostic differences among species, due to the convergence in allometric relationships within smaller size ranges. Leaf orientation and spacing Leaf orientation varies among species, some like P retrospectans and P fuscella have transversely orientated leaves, while others like P bantamensis and P vitiensis have nearly longitudinally orientated leaves. Leaf spacing may show different tendencies among species, particularly closely related species, which provide clues to identity though these are probably best regarded as non-definitive clues only. As an example, P fasciculata typically has imbricate primary shoot leaves, while P subfasciculata typically has remote to contiguous primary shoot leaves, so an initial appraisal of leaf spacing can be corroborated or falsified by assessment of leaf shape and dentition. Plagiochila apatila and P nebulosa have leaves more closely spaced than some other sect. Vagae species such as P minax. Other species express considerable variation in leaf spacing, such as P incurvicolla within which individuals vary from taller morphs with widely remote leaves to short plants with contiguous to imbricate leaves. Plagiochila deltoidea is another species in which leaf spacing varies, so this character should be used with a degree of discretion. Leaf dentition Leaf dentition varies among species and is another critical source of species circumscribing characters. Teeth vary from triangular with a broad base and composed of quadrate to subquadrate cells, to spinose with a narrow base and composed of elongated cells to dilate and composed of elongate rectangular cells. The number of teeth on leaf margin also serves to differentiate among some species, as does their distribution. In particular the presence of teeth on the dorsal leaf margin is important in distinguishing between some similar pairs of species, for example P sydneyensis from other species of sect. Cucullatae, and P baylisii from P circinalis. The number of teeth shows a broad positive correlation with leaf size; within species the larger the leaf the more teeth on its margin. Leaf cells A thickened border is present in some species of sect. Denticulatae such as P gigantea and P retrospectans. This border consists of continuous golden-brown pigmented thickening on the walls of the marginal two or three tiers of leaf cells, and this is sometimes discernable with a hand lens in the field. Plagiochila lamellata may also produce a similar leaf border in the same manner. The presence of a leaf border is a feature of most, but not all species of sect. Denticulatae, being absent from P gregaria or Pfragmentissima, and variably expressed in P rutlandii. A revision of Australian Plagiochila (Lophocoleinae: Jungermanniopsida) Telopea 21: 187-380, 2018 195 The degree of trigone development varies among Plagiochila species, some species such as R circinalis are capable of producing block-like trigones, while others such as P. bantamensis produce triangular trigones only. So, while this character is potentially informative, the capacity for intra-specific variation in trigone production limits this somewhat. Leaf-cell size and thickening both vary within and among species and have not been critically assessed as part of this study, so are not used as species circumscribing characters. However, species of sect. Cucullatae generally have larger, more leptodermous cells than other Plagiochila species, and this gives the plants a distinctive glassy appearance in the herbarium. Leaf cell size provides a useful source of characters for differentiating between P apatila and R nebulosa, as discussed below P nebulosa has distinctly elongate leaf marginal cells and leaf teeth cells in comparison to P apatila. Underleaves Many Plagiochila species produce underleaves, though in most these underleaves are highly reduced. These reduced underleaves are often triangular, but some species have bi-lobed vestigial underleaves. Plagiochila streimannii produces what are probably the most conspicuous and well-developed underleaves among Australasian species. Plagiochila bantamensis also produces conspicuous underleaves, and in these two species the presence of large underleaves serves to differentiate them from others in their respective sections that do not produce underleaves. However, both species are distinctive and can be recognized without assessing the underleaves. Multiramous ciliiform underleaves are produced by P arbuscula, P alta, P pacifica, and P trispicata, but these fragment and dislocate to the point of absence from mature shoot sectors, except for P pacifica in which underleaf remnants, comprising the basal-most cells of the underleaf remain on mature shoot sectors. In all species of the P arbuscula complex the fully-formed underleaves can only be found among the embryonic leaves at the shoot apex. Paraphyllia and lamellae. Paraphyllia and lamellae are produced by several species and are usually consistently produced by the species that possesses them. The distribution of paraphyllia and lamellae on the stem varies among species and this is useful for identification. Paraphyllia may may be restricted to the dorsal or the ventral sides of the stem, as in P. circumdentata, and P. kirkii or distributed all around the stem surface as in P. abietina or confined to the ventral stem surface as in P. obtusa and P. streimannii. In Plagiochila abietina paraphyllia are usually uniseriate projections, but larger paraphyllia comprising small flanges of tissue, sometimes bearing one or two teeth, are also produced. Large branched and ciliate paraphyllia are produced by P. obtusa and P. streimannii; in both these species paraphyllia are restricted to the ventral side of the stem. Paraphyllia in P. circumdentata and P. kirkii are chartaceous, but in the latter some paraphyllia are long and approach lamellae. A single long linear lamella is present on the dorsal stem surface adjacent each leaf insertion line in P. lamellata. Asexual reproduction Several modes of asexual reproduction occur in Australian Plagiochila species. The manifestation of these various modes is more informative of broader relationships than species circumscription, nevertheless the presence of a given type of asexual reproduction can often usefully localize an unknown plant to one or two likely groups of species. Most species of sect. Vagae produce gemmae borne on the ventral surface of the leaves. These form by budding, then proliferation of single leaf cells, and quickly assume the form of a small shoot. They may be particularly dense in some individuals. Several species reproduce via caducous leaves, and these may dislocate whole or in pieces. The leaves of P. minutissima and P. spinulosa dislocate as a whole from their base, while the leaves of P. bantamensis dislocate as fragments starting at the leaf apex and working inward toward the stem as the leaf ages. Male bracts The male bracts of Plagiochila exhibit useful variation. The male bracts in species of sect. Denticulatae are remote to contiguous, and the bract lobe rolls down and sits below the next male bract, so stops below, an arrangement called hypostatic. The other arrangement is exemplified by species of sect. Vagae whose male bracts are imbricate, the bract lobe then laying upon the next male bract, so stopping on, an arrangement called epistatic. Male bract lobes may be toothed or entire, and their apex rounded to acute, and some similar species pairs may be readily distinguished on this basis, for example P. strombifolia has entire male bract lobes, while P. fasciculata has dentate male bract lobes. 196 Telopea 21: 187-380, 2018 Renner Taxonomic Treatment Plagiochila (Dumort.) Dumort. Recueil Observ. Jungerm. 14 (1835) Basionym: Radula sect. Plagiochila Dumort., Syll. Jungerm. Europ. 42 (1831) Type: Plagiochila asplenioides (L.) Dumort. Recueil Observ. Jungerm. 14 (1835) Shoots in nearly all species divided into microphyllous basal stolon and leafy upper sector. Branching within the stolon lateral- or ventral- intercalary. Vegetative branching within the leafy sector various, Frullania-type, lateral-intercalary, or ventral-intercalary. Leaves succubously inserted, sometimes nearly transverse, usually unlobed, rarely bifid, usually with toothed margins, teeth various. Underleaves usually reduced or absent, but in sect. Cucullatae well developed, bifid, and ciliate. Stems with differentiated cortex, walls typically thickened and brown pigmented. Dioecious. Androecia intercalary on shoots. Gynoecia terminal, on primary shoots or any subordinate shoot order, in some species such as P abietina on abbreviated shoots, with two leaf-like bracts and sometimes a bracteole. Perianth laterally compressed, ventral face reduced or absent. Subfloral innovations by lateral and/or ventral intercalary branching. Key to Australasian Plagiochila. 1 Leafy shoots bipinnate, pinnate or irregular. Vegetative branching Frullania-type or lateral-intercalary, not pseudodichotomous. Asexual production, if present, by caducous leaves. Paraphyllia, if present, confined to dorsal stem surface or distributed on all stem surfaces.13 1 Leafy shoots pseudodichotomous, vegetative branching Frullania-type. Asexual reproduction, if present, by gemmae produced from the leaf ventral surface. Paraphyllia, if present, confined to the ventral stem surface.sect. Vagae 2 2 Stems with paraphyllia on their ventral surface.3 2 Stems without paraphyllia on their ventral surface.4 3 Leaves falcate, with 2-7 triangular teeth around the apex. Underleaves conspicuous, larger than paraphyllia.P streimannii 3 Leaves elliptic, with up to 25 spinose-ciliate teeth, sometimes on all margins. Underleaves similar in size to paraphyllia.P obtusa 4 Leaves on secondary, tertiary and quaternary shoots rectangular to narrowly-rectangular, apex bifid, often no other teeth present on leaf margin.P daviesiana 4 Leaves on secondary, tertiary and quaternary shoots elliptic to ovate to ovate-triangular, apex truncate to rounded, with two or more teeth at apex and additional teeth on ventral leaf margin at least.5 5 Ventral leaf margin undulate.P norfolkiensis 5 Ventral leaf margin plane.6 6 Leaf margins conspicuously dentate.7 6 Leaf margins often entire, or with inconspicuous triangular teeth.8 7 Leaves triangular-oblong, apex truncate, margins entire.P acutifolia 7 Leaves elliptic-oblong, apex rounded or truncate, margins usually with small triangular teeth.P paucidens 8 Primary shoots 3.2-3.7 mm wide.9 8 Primary shoots 5.0-5.5 mm wide.11 9 Leaves on primary shoots oblong-triangular.10 9 Leaves on primary shoots triangular-ovate .P queenslandica 10 Leaves on primary shoots with 14-20 spinose teeth regularly spaced around apex and along ventral margin; cells in teeth elongate, narrowly rectangular. Male bract lobes obtuse, otherwise entire.P nebulosa

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