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rbcL data reveal two monophyletic groups of filmy ferns (Filicopsida: Hymenophyllaceae)¹

²Department of Botany, The Field Museum of Natural History, 1400 S. Lake Shore Drive, Chicago, Illinois 60605-2496 USA ³University Herbarium, 1001 Valley Life Sciences Building #2465, University of California, Berkeley, California 94720-2465 USA ⁴Laboratoire de Paléobotanique et Paléoécologie, FR3-CNRS "Institut d'Écologie," Université Pierre et Marie Curie, 12 rue Cuvier, F-75005 Paris, France

Received for publication February 15, 2000. Accepted for publication July 18, 2000.

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

 
The "filmy fern" family, Hymenophyllaceae, is traditionally partitioned into two principal genera, Trichomanes s.l. (sensu lato) and Hymenophyllum s.l., based upon sorus shape characters. This basic split in the family has been widely debated this past century and hence was evaluated here by using rbcL nucleotide sequence data in a phylogenetic study of 26 filmy ferns and nine outgroup taxa. Our results confirm the monophyly of the family and provide robust support for two monophyletic groups that correspond to the two classical genera. In addition, we show that some taxa of uncertain affinity, such as the monotypic genera Cardiomanes and Serpyllopsis, and at least one species of Microtrichomanes, are convincingly included within Hymenophyllum s.l. The tubular- or conical-based sorus that typifies Trichomanes s.l. and Cardiomanes, the most basal member of Hymenophyllum s.l., is a plesiomorphic character state for the family. Tubular-based sori occurring in other members of Hymenophyllum s.l. are most likely derived independently and more than one time. While rbcL data are able to provide a well-supported phylogenetic estimate within Trichomanes s.l., they are inadequate for resolving relationships within Hymenophyllum s.l., which will require data from additional sources. This disparity in resolution reflects differential rates of evolution for rbcL within Hymenophyllaceae.

Key Words: filmy ferns • Hymenophyllaceae • Hymenophyllum • phylogeny • rbcL • Trichomanes

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

 
The Hymenophyllaceae, or "filmy fern" family, is the largest (>600 species) and most diverse basal lineage of leptosporangiate ferns, displaying extreme morphological and ecological diversity (reviewed in Dubuisson, 1996 ). Disagreement over delimitation of genera and infrageneric taxa far exceeds that in any other fern family, and intrafamilial phylogenetic relationships have been, until now, speculative. Traditionally, two genera, Trichomanes and Hymenophyllum, have been recognized on the basis of their marginal indusiate soral morphology ("indusia" are synonymous with "involucres" in this family) and the filiform to clavate, exserted or included receptacle that bears the sporangia. Trichomanes s.l. is characterized by cup-shaped or campanulate involucres that are sometimes tubular throughout or at least in the proximal portion (Fig. 1C), while Hymenophyllum s.l. typically exhibits bivalved involucres (Fig. 1D). Iwatsuki (1977) , however, noted that there is a continuous series of involucral types from cup-shaped to bivalved, and consequently he rejected the traditional bigeneric classification system, recognizing instead eight genera. In another major classification, Morton (1968) recognized the two classical genera, plus four additional monotypic genera, Hymenoglossum, Serpyllopsis, Rosenstockia, and Cardiomanes. The remarkable morphological diversity in the family has encouraged several pteridologists to propose additional genera (see especially Copeland, 1933, 1937, 1938 ), and this variation is also reflected in Morton's (1968) classification at the subgenus and section levels. The Hymenophyllaceae has been subdivided into as many as 42 genera by some authorities, and taxonomic treatments and classifications often adopt genera with vastly different circumscriptions (Copeland, 1938, 1947 ; Morton, 1968 ; Pichi Sermolli, 1977 ; Iwatsuki, 1984, 1985, 1990 ).

View larger version (54K): [in this window] [in a new window]   Fig. 1. Examples of fronds and sori of Hymenophyllaceae. (A) Serpyllopsis caespitosa (Gaudich.) C. Chr., habit and sorus with cup-shaped base, slightly bivalvate at tip, receptacle exserted; based on Hooker (1844 , Table XL, B [3,4]) and on Freas 127 (F), from Chile. (B) Cardiomanes reniforme (G. Forst.) C. Presl, habit and tubular-based sori with long-exserted receptacles; based on Dobbie and Crookes (1951 , pp. 106 and 107) and on Chamberlain s.n. (F), from New Zealand. (C) Trichomanes hymenoides Hedw., campanulate tubular-based sori with bilabiate mouths and included receptacles; reproduced with permission from Tryon and Stolze (1989 , fig. 12d); (D) Hymenophyllum fucoides (Sw.) Sw., bivalvate sori with included receptacles; reproduced with permission from Tryon and Stolze (1989 , fig. 11b)

We have initiated a study using the chloroplast rbcL gene to assess broad evolutionary relationships within Hymenophyllaceae. Dubuisson (1996, 1997a) had already established that Trichomanes s.l. (hereafter often called simply Trichomanes, unless a more restricted concept is discussed) appeared to be monophyletic and that rbcL was useful for resolving relationships within the genus, with the exception of some basal branches. The monophyly and circumscription of Hymenophyllum s.l. (hereafter often called simply Hymenophyllum, unless a more restricted concept is discussed), however, are more uncertain (Copeland, 1937, 1947 ; Morton, 1968 ; Pichi Sermolli, 1977 ; Iwatsuki, 1984, 1985, 1990 ). Only three rbcL sequences of Hymenophyllum were included by Dubuisson (1997a) , and these are not representative of the diversity within that genus. We have expanded the sampling for Trichomanes and especially for Hymenophyllum to investigate whether the traditional bigeneric classification system is upheld or whether the apparent monophyly of Trichomanes is disrupted by the inclusion of additional species of Hymenophyllum. A robust phylogeny will permit us to examine more critically the evolutionary patterns of soral and indusial morphology, key characters traditionally used in filmy fern systematics. In addition, we evaluate the general utility of rbcL for future phylogenetic work in Hymenophyllaceae.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

 
Taxonomic sampling and nomenclature
Our ingroup represents a broad sampling of the morphological, ecological, and geographical diversity within Trichomanes and Hymenophyllum. Twenty-six filmy ferns are listed in Table 1, together with comments on their geographical distribution, ecology, taxonomic attribution according to various pteridological authorities, and GenBank accession numbers; voucher information is indicated for the ten taxa for which we provide new rbcL data. For the purpose of presenting the results and discussion (and in Figs. 3–5), we adopt the classification of Morton (1968) . Equivalent names in other classifications (e.g., Copeland, 1947 ; Pichi Sermolli, 1977 ; Iwatsuki, 1985, 1990 ) are different, and some of these differences are summarized in Table 1.

View larger version (34K): [in this window] [in a new window]   Fig. 3. Strict consensus of 31 most parsimonious trees (tree length = 1968 steps) resulting from an equally weighted analysis. HYM = Hymenophyllaceae; T = Trichomanes s.l.; H = Hymenophyllum s.l.; nomenclature follows Morton (1968) with his sectional names provided in parentheses (see Table 1 for Morton's classification). Roman numerals I and II denote the two most inclusive, well-supported clades within Trichomanes s.l. Numbers above branches are bootstrap percentage values >50%, followed by decay values after slash. Branches with thick lines are the most robustly supported (BS 87%, decay value 5). The tree was rooted with Angiopteris.

Species belonging to Morton's (1968) "unclassified" (unplaced sectional name) Trichomanes sect. Microtrichomanes are problematic and have been treated variously: (1) within Hymenophyllum (Copeland, 1938 ), (2) in an unresolved position and of probable hybrid origin between Trichomanes and Hymenophyllum (Morton, 1968 ), (3) in a basal position in the "Hymenophylloids" (Pichi Sermolli, 1977 ), or (4) as a heterogeneous group, provisionally included in Trichomanes (Iwatsuki, 1975, 1985, 1990 ). We selected T. taeniatum Copel. to represent this section because it is morphologically similar and probably closely related to the type species of Microtrichomanes, T. digitatum Sw., which was unavailable for study (see Iwatsuki, 1975 , p. 123, who treated M. digitatum and M. taeniatum as close allies and representing Microtrichomanes s.s. [sensu stricto]).

Representatives of Hymenophyllum included here are taxa from the three most species-rich and widespread subgenera of Morton (1968) : subg. Mecodium (two spp.), subg. Sphaerocionium (three spp.), and subg. Hymenophyllum (three spp.). We include also the type and probable sole representative of Hymenophyllum subg. Hemicyatheon, H. baileyanum Domin, from Australia. Seven of these nine Hymenophyllum species are newly sequenced here (Table 1).

We also investigated two monotypic filmy fern genera of uncertain affinity, Serpyllopsis and Cardiomanes. The mosslike segregate Serpyllopsis caespitosa (Gaudich.) C. Chr. (Fig. 1A) is endemic to southernmost South America, the Falkland Islands, and Juan Fernández. It was first described as a Trichomanes but it has often been suggested that it belongs to Hymenophyllum (Copeland, 1938, 1947 ; Morton, 1968 ; Iwatsuki, 1990 ; Schneider, 1996 , citing evidence from protoxylem development in roots); however, Pichi Sermolli (1977 : 414–415, fig. 13) included it among his "Trichomanoids." Cardiomanes reniforme (G. Forst.) C. Presl (Fig. 1B), endemic to New Zealand, has often been placed in Trichomanes, but its affinities are equally uncertain (Copeland, 1947 ; Morton, 1968 ; Iwatsuki, 1984, 1990 ). Recently, it has been considered the sole representative of the subfamily Cardiomanoideae (Iwatsuki, 1990 ).

Although the Hymenophyllaceae is known to be among the basal leptosporangiate fern lineages, its sister group is as yet undetermined (Hasebe et al., 1995 ; Pryer, Smith, and Skog, 1995 ); therefore, a broad sampling of eight leptosporangiate ferns was included to evaluate the monophyly of Hymenophyllaceae. Together with their GenBank accession numbers (the prefix GBAN- has been added to link the online version of American Journal of Botany to GenBank, but is not part of the actual GenBank accession number), these include: Osmundaceae, Osmunda cinnamomea L. (GBAN-D14882); Schizaeaceae, Lygodium japonicum (Thunb.) Sw. (GBAN-U05632); Gleicheniaceae, Diplopterygium glaucum (Thunb. ex Houtt.) Nakai (GBAN-U05624; published as Gleichenia japonica Spreng., a synonym), Matoniaceae, Matonia pectinata R. Br. (GBAN-U05634), Dipteridaceae, Dipteris conjugata Reinw. (GBAN-U05620); Dicksoniaceae, Dicksonia antarctica Labill. (GBAN-U05919); Polypodiaceae, Polypodium glycyrrhiza D. C. Eaton (GBAN-U21146); and Pteridaceae, Pteris vittata L. (GBAN-U05941). A eusporangiate fern representative from the Marattiaceae, Angiopteris evecta (G. Forst.) Hoffm. (GBAN-L11052), was used to root the trees.

DNA isolation, amplification, and sequencing
Filmy ferns are often epiphytic and grow intermingled with minute, habitally similar bryophytes. Silica-dried leaf material for all taxa for which new rbcL data are presented here (see Table 1) was carefully examined under a dissecting microscope to remove possible contaminants. Leaf tissues were pulverized using a mortar and pestle and liquid nitrogen. DNA was isolated following the procedure described by Dubuisson (1997a) , with the exception of using 5.5% DTAB buffer rather than 2% CTAB.

Approximately 1.4 kb of the rbcL gene were amplified from genomic DNA by polymerase chain reaction (PCR) using primers aF and 1379R or M1390R (Fig. 2). Amplifications were carried out in 25-µL reactions under standard conditions on a PTC 200 DNA Engine thermal cycler (MJ Research, Watertown, Massachusetts, USA). The reaction mixture typically contained 1.0 U of Amplitaq Polymerase (Perkin-Elmer Biosystems, Foster City, California, USA), 10 x PCR buffer, 2.0 mmol/L MgCl₂, 0.04 mmol/L of each deoxynucleotide (dNTP), 500 nmol/L of each amplification primer, 50 ng of genomic template DNA, and purified water to volume.

View larger version (15K): [in this window] [in a new window]   Fig. 2. Sequences and approximate annealing sites of primers used for rbcL amplification1 and sequencing of filmy ferns. Some primers were previously published in Hasebe et al. (1994) , Dubuisson (1996) , and Lewis, Mishler, and Vilgalys (1997)

Sequence alignment and phylogenetic analyses
The final rbcL sequences were aligned by eye using PAUP* version 4.0b2a (Swofford, 1999 ). All phylogenetic analyses were conducted using PAUP* on Macintosh Power PCs.

Maximum parsimony and maximum likelihood analyses were used to estimate phylogenetic relationships. For the maximum parsimony analyses, the rbcL character-state changes were weighted equally in the first analysis and unequally in the second. For the latter analysis, a priori weights were calculated from the data matrix for the character-state changes associated with each codon position. Step matrices were constructed for the first-, second-, and third-codon positions. For each codon position, the average frequency for all six pairs (AC, AG, AT, CG, CT, GT) of possible transformational changes (without polarity) was empirically calculated and converted to percentages. These probabilities of reciprocal change were converted to costs of changes using the negative natural logarithm of the probability (Felsenstein, 1981 ; Wheeler, 1990 ; Maddison and Maddison, 1992 , pp. 60–61; Lutzoni, 1997 ). Each of these costs was rounded off to the second decimal point and used to construct a symmetric step matrix for each codon position. These three step matrices were implemented simultaneously in the Assumptions block of the rbcL Nexus file. PAUP* automatically tested each step matrix for internal consistency and checked that triangle inequality was not violated. The alignment (including step matrices) is available on request as a Nexus file from the first author.

The parsimony heuristic searches for both the equally and unequally weighted analyses were conducted using 1000 random-addition sequence replicates, tree bisection-reconnection (TBR) branch swapping, MULTrees option on, and collapse zero-length branches off. Support for the internodes of the most parsimonious trees in both analyses was estimated by 1000 bootstrap (BS) replicates (Felsenstein, 1985 ) using a heuristic search with ten random-addition sequence replicates per bootstrap replicate, TBR branch swapping, MULTrees option on, and collapse zero-length branches off. Decay values for the equally weighted analysis were determined by examining the strict consensus of trees one to five steps longer than the shortest trees.

The selection of an evolutionary model for the maximum likelihood analyses for the same data was carried out by implementing, in an iterative fashion, increasingly more complex models of sequence evolution (e.g., Felsenstein [F81], Hasegawa, Kishino, and Yano [HKY85], Tamura-Nei [TrN], and general time-reversible [GTR]), as recommended by Huelsenbeck and Crandall (1997, see their Table 1 in particular). This procedure was accomplished by using the topology generated from the unequally weighted parsimony analysis. The likelihood ratio test statistic,–2 log (twice the difference between the log-likelihoods of two models), is ² distributed and was used to test whether increasing the number of parameters for each model provided a significant improvement in the likelihood (Page and Holmes, 1998 ). The best likelihood was achieved using the general time-reversible (GTR) model, accommodating unequal nucleotide frequencies and different probabilities for each of six substitution types, plus heterogeneous rates of change (four rate categories) across sites following a discrete approximation of the gamma distribution () (Yang, 1993, 1994 ). Nucleotide frequencies, substitution rate matrices, and distribution shape parameters were estimated via maximum likelihood.

For the search using maximum likelihood as the optimization criterion, 60 random-addition sequence searches were conducted, each using TBR branch swapping and MULTrees option on. Support for the internodes of the topology with the best likelihood was estimated by 100 bootstrap replicates with two random-addition sequence replicates per bootstrap replicate, using parameters identical to those used to find the most likely tree.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

 
The rbcL data set included 1206 bp for each of 35 taxa and no positional homology ambiguities. Of these, 660 characters were constant, 126 were variable but parsimony-uninformative, and 420 were parsimony-informative (79% in third codon position) in the equally weighted parsimony analysis, which found 31 equally most parsimonious trees at 1968 steps (excluding uninformative characters, CI [consistency index] = 0.364; RI [retention index] = 0.516). The strict consensus tree is shown in Fig. 3. The implementation of step matrices in the unequally weighted parsimony analysis increased the number of parsimony-informative characters to 428. This differentially weighted parsimony analysis yielded one most parsimonious tree (Fig. 4) at 3107.53 steps (excluding uninformative characters, CI = 0.373; RI = 0.517). The most likely tree recovered using the maximum likelihood optimization criterion (ln likelihood = –8669.5974) is shown in Fig. 5.

View larger version (30K): [in this window] [in a new window]   Fig. 4. Single most parsimonious tree (tree length = 3107.53 steps) resulting from the unequally weighted analysis using empirically calculated, symmetric step matrices (see text). HYM = Hymenophyllaceae; T = Trichomanes s.l.; H = Hymenophyllum s.l.; nomenclature follows Morton (1968) with his sectional names provided in parentheses (see Table 1 for Morton's classification). Roman numerals I and II denote the two most inclusive, well-supported clades within Trichomanes s.l. Numbers above branches are bootstrap percentage values >50%. Branches with thick lines are the most robustly supported (BS 85%). The tree was rooted with Angiopteris. Scale indicates a branch length corresponding to 50 character-state changes

View larger version (29K): [in this window] [in a new window]   Fig. 5. Most likely topology (ln likelihood = –8669.5974) resulting from the maximum likelihood analysis. HYM = Hymenophyllaceae; T = Trichomanes s.l.; H = Hymenophyllum s.l.; nomenclature follows Morton (1968) with his sectional names provided in parentheses (see Table 1 for Morton's classification). Roman numerals I and II denote the two most inclusive, well-supported groups within Trichomanes s.l. Numbers above branches are bootstrap percentage values >50%. Branches with thick lines are the most robustly supported (BS 84%). The tree was rooted with Angiopteris. Scale indicates a branch length corresponding to 0.05 substitutions/site

Within Trichomanes (group T), there is robust support for two inclusive subgroups (BS 88) in all three analyses (subgroups I and II; Figs. 3–5): T. minutum to T. ekmanii and T. alatum to T. elegans; subgroup I is fully resolved and mostly well supported (BS 73%). The T. alatum to T. tamarisciforme group, seen only in the maximum likelihood analysis (Fig. 5), is weakly supported (BS < 50). The T. javanicum + T. tamarisciforme group, seen in the unequally weighted parsimony analysis and the maximum likelihood analysis (Figs. 4 and 5), is also weakly supported (BS 69).

Within Hymenophyllum (group H), Cardiomanes reniforme is always most basal and sister to all other species of Hymenophyllum; however, this internode is weakly supported (BS 67). Only two nodes are well supported (BS 99) within Hymenophyllum in all three analyses (Figs. 3–5): H. apiculatum + H. polyanthos and H. hirsutum + H. ferrugineum. Support for T. taeniatum + H. lanceolatum is weak to moderate (BS 70), and all other nodes, especially those concerning relationships of H. tunbrigense, H. fucoides, and H. secundum, are not strongly supported (BS 59) (Figs. 3–5). Serpyllopsis caespitosa and T. (Microtrichomanes) taeniatum have been considered to be of uncertain affinity, but support for their inclusion in the Hymenophyllum group is convincing (Figs. 3–5). Their exact relationships within that group, however, remain in doubt.

Relationships among other leptosporangiate fern representatives were (Figs. 3–5) shown not to differ unexpectedly from previously published studies (e.g., Hasebe et al., 1995 ; Pryer, Smith, and Skog, 1995 ).

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

 
The monophyly of Hymenophyllaceae has never been disputed and is corroborated by this study (Figs. 3–5). The peculiar and distinctive marginal sori (Fig. 1) do not occur in any other fern family, and the filmy nature of the leaf (blade usually only one cell thick) is also rare outside Hymenophyllaceae. The only other ferns with similarly thin blades (and also lacking stomata) occur in Hymenophyllopsidaceae, a monogeneric family with eight species nearly restricted to sandstone tepuis in the Guayana Shield, in Venezuela and adjacent countries, but Hymenophyllopsis differs in details of the sori and indument. Although Hymenophyllopsis has sometimes been considered a close relative of Hymenophyllacaeae (e.g., Mickel, 1973 ; Stevenson and Loconte, 1996 ), other morphological studies do not support this hypothesis (Schneider, 1996 ). Recent molecular evidence suggests that Hymenophyllopsis is more closely related to tree ferns (Wolf et al., 1999 ). Our study does not provide new clues as to the position of Hymenophyllaceae among basal leptosporangiate ferns (Pryer, Smith, and Skog, 1995 ; Wolf et al., 1998 ). This is not unexpected, given the reduced sampling of taxa ouside of Hymenophyllaceae, and was not the focus of this paper.

A basal dichotomy of two monophyletic groups within Hymenophyllaceae, which corresponds to the two classical genera Trichomanes and Hymenophyllum, is robustly supported (Figs. 3–5), regardless of the analytical approach (parsimony or likelihood). This is a significant finding that supports the traditional classificatory dichotomy for the family (e.g., Morton, 1968 ), whether at the generic or some suprageneric rank. Fragmentation of the family into numerous genera to accommodate the diversity in morphological variation that is observed (e.g., Copeland, 1938, 1947 ; Pichi Sermolli, 1977 ) cannot be specifically addressed from our data set because sampling is still not adequate in many groups. Our study does not preclude the possibility that it may be desirable, with more complete sampling and the addition of evidence from other genes, to recognize some of the most well supported and monophyletic of the segregates at generic rank. However, the recognition by Iwatsuki (1990) of two subfamilies, Hymenophylloideae (in which he included Hymenoglossum, Serpyllopsis, Trichomanes, Sphaerocionium, Hymenophyllum, Crepidomanes, and Cephalomanes) and Cardiomanoideae (Cardiomanes), is not supported in our analysis, and the monophyly of several of his segregate genera (e.g., Cephalomanes, Crepidomanes, Hymenophyllum, and Trichomanes) is seriously called into question (cf. Iwatsuki classification indicated in Table 1 with Figs. 3–5). Furthermore, we suggest from our preliminary trees that the polygeneric classificatory systems of Copeland (1938, 1947) and Pichi Sermolli (1977) need reexamination in many aspects.

Trichomanes s.l. (group T; Figs. 3–5)
Increasing the sampling within Hymenophyllum had no impact on the previously proposed monophyly of Trichomanes (Dubuisson, 1997a ). Pichi Sermolli (1977) also proposed the monophyly of the Trichomanes group (his "Trichomanoids"), in which he recognized 26 genera, including all 18 "trichomanoid" genera of Copeland (1938) , plus eight additional segregate genera. This group has been informally referred to the tribe Trichomaneae (Schneider, 1996, 2000 ; the tribal name first validly published by Dumortier, 1829 , in a different family), and it corresponds to Trichomanes sensu Morton (1968) and to the sum of the three genera Cephalomanes, Trichomanes, and Crepidomanes sensu Iwatsuki (1990) , but excludes Microtrichomanes (included by Iwatsuki in Crepidomanes). From our analyses, none of Iwatsuki's three "trichomanoid" genera appear monophyletic. In our sampling (cf. Table 1 and Figs. 3–5), Iwatsuki's Cephalomanes would include T. thysanostomum, T. elegans, T. javanicum, and T. tamarisciforme; Trichomanes would include T. membranaceum, T. pinnatinervium, T. ekmanii, T. alatum, T. pinnatum, and T. osmundoides; and Crepidomanes would include T. minutum, T. bipunctatum, T. speciosum, T. radicans, and T. taeniatum.

Copeland (1947 , p. 43, figure) did not recognize the trichomanoids as monophyletic, but rather depicted taxa (groups of genera) as arising twice from "proto-hymenophyllaceous" ancestors. Iwatsuki has been the only contemporary pteridologist to criticize the monophyly of Trichomanes, using as his argument the nearly continuous morphological series from bivalved (hymenophylloid) to campanulate (trichomanoid) sori. He attempted to show that cup-shaped or campanulate involucres and bivalved involucres derive from different ontogenetic processes involving the base and margin of the sorus. The occurrence of intermediate shapes was postulated to be a result of varying contributions of both parts of the involucre during development (Iwatsuki, 1977 ). It is our observation that sorus shape in Hymenophyllaceae is not so continuous as Iwatsuki (1977) proposed, and that in Trichomanes (excluding Microtrichomanes), all species exhibit a tubular base even though in some groups the involucral lips are well developed and somewhat valvate.

The reaffirmed monophyly of Trichomanes s.l. provides a framework for further investigations focusing on this group, including both morphological and cytological studies. Morton (1968) , Braithwaite (1969, 1975) , Pichi Sermolli (1977) , Tryon and Tryon (1982) , and Dubuisson, Hébant-Mauri, and Galtier (1998) suggested that chromosome numbers might be potentially useful for the systematics of trichomanoid genera. Similarly, detailed comparative studies of root and rhizome morphology and corresponding sporophyte growth forms (e.g., Schneider, 1996, 2000 ), and of gametophytes (e.g., Dassler and Farrar, 1997 ), also promise to yield phylogenetically informative characters.

From this study and previous ones by Dubuisson (1997a, b) and Dubuisson, Hébant-Mauri, and Galtier (1998) , the following major taxonomic conclusion is warranted: Morton's (1968) subg. Didymoglossum (which includes sections Didymoglossum, Microgonium, and Lecanium; cf. Morton's classification in Table 1 with Figs. 3–5), mostly neotropical but with a few species in Africa and Asia, forms a cohesive and well-supported group. In addition, there is growing evidence supporting several other clades or relationships of significance: an Old World–New World clade, comprising most (perhaps all?) of Morton's (1968) subg. Trichomanes (including his sections Gonocormus, Crepidomanes, and Lacosteopsis), and part of his subg. Pachychaetum (sect. Nesopteris); and a sister group relationship between this last clade and subg. Didymoglossum (Figs. 3–5). Several additional critical taxa need investigation before taxon sampling can be considered comprehensive enough to reassess classification within the trichomanoid group. For example, species belonging to Morton's (1968) Trichomanes sect. Callistopteris (Cephalomanes sensu Iwatsuki) are of special interest because Dassler and Farrar (1997) , based on a study of gametophyte structures and gemmae, suggested they might be the most basal group within Trichomanes s.l.

Hymenophyllum s.l. (group H; Figs. 3–5)
In our results, Hymenophyllum s.l. includes also Cardiomanes reniforme, Serpyllopsis caespitosa, and Trichomanes (Microtrichomanes) taeniatum, and is robustly supported as monophyletic. The monophyly of Hymenophyllum was first challenged by Copeland (1938 , p. 2), who presented a phyletic diagram in which taxa here referred to Hymenophyllum s.l. appear in at least seven distinct lineages. Morton (1968) , in the primary couplet of his key to genera, recognized Hymenophyllum s.s. (comprising >99% of Hymenophyllum s.l.) and three monotypic genera, Serpyllopsis caespitosa (Fig. 1A), Rosenstockia rolandi-principis (Rosenst.) Copel., and Hymenoglossum cruentum (Cav.) C. Presl, as exhibiting an "involucre bivalved throughout or at least to the middle, the immersed part, if any, cuplike or conic and not tubular"; while Cardiomanes reniforme and Trichomanes s.l. shared "involucre tubular" (Fig. 1B and C).

Iwatsuki (1984, 1990) also recognized Cardiomanes, Serpyllopsis, and Hymenoglossum as distinct, but he subdivided Morton's (1968) Hymenophyllum s.s. into Hymenophyllum (including Rosenstockia) and Sphaerocionium. As in the trichomanoids, Iwatsuki's hymenophylloid genera do not appear monophyletic and only subgenus Mecodium (sensu both Iwatsuki and Morton) is strongly supported in our sampling (Figs. 3–5). It is impossible to evaluate with our data set all of the segregates recognized within Hymenophyllum s.l. by Iwatsuki (1984, 1990) and Morton (1968) , because our taxon sampling is insufficient. With a larger data set, and additional genes, it may well be that certain segregates, e.g., Mecodium, will be confirmed to be monophyletic.

Figures 3–5 show that Cardiomanes, a genus sometimes put in its own subfamily, Cardiomanoideae (Iwatsuki, 1984, 1990 ), is weakly supported as sister to a group that has been informally referred to the tribe Hymenophylleae (Schneider, 1996, 2000 ), which corresponds to Morton's (1968) genera Hymenophyllum s.s. plus Serpyllopsis and Trichomanes sect. Flabellata [= Microtrichomanes] and to Iwatsuki's (1984, 1990) genera Hymenophyllum s.s. and Sphaerocionium. Although the basal position of Cardiomanes within Hymenophyllum s.l. is not really surprising, by virtue of its peculiar soral, blade (Fig. 1B), and gametophyte (Holloway, 1944 ) characteristics, this is the first time that a close relationship to Hymenophyllum has been explicitly demonstrated. Holloway (1944) suggested that Cardiomanes might have closer affinities to Hymenophyllum than to Trichomanes based on observed gametophyte, embryo, and stele characters. This phylogenetic position is in disagreement with the proposition of Pichi Sermolli (1977) who included it in his "Trichomanoids," presumably because of its tubular-based involucres. Other authorities (e.g., Copeland, 1947 ; Morton, 1968 ; Iwatsuki, 1984, 1990 ) are either noncommittal about its relationships (no doubt because of the unusual features of Cardiomanes, including sori and blade), or suggest, rather cautiously, that it may be part of the trichomanoids.

Interestingly, our results suggest that tubular-based involucres are a plesiomorphic character state for Hymenophyllaceae, with a single transition to bivalved involucres taking place on the branch uniting Cardiomanes to all other taxa in this group (Fig. 6). There is considerable involucral shape variation within Hymenophyllum s.l. that requires a careful morphological and developmental comparative study across a broad spectrum of taxa, however, independent character-state reversals to tubular-based involucres are likely to be confirmed (e.g., Microtrichomanes, and perhaps Serpyllopsis; Fig. 6).

View larger version (59K): [in this window] [in a new window]   Fig. 6. Soral evolution in Hymenophyllaceae plotted onto the same topology shown in Fig. 4 , with gains and losses among character states equally weighted. The tubular- or conical-based involucres are a plesiomorphic character state for the family, with a single transition to bivalved involucres taking place on the branch uniting Cardiomanes to all other taxa in Hymenophyllum s.l. Without more detailed study, Serpyllopsis cannot be assigned to either the tubular or bivalved involucral state with confidence (cf. Copeland, 1947 ; Morton, 1968 ; Iwatsuki, 1990 ). Tubular-based involucres appearing in other members of Hymenophyllum s.l. (including those taxa not shown here) are most probably derived independently and more than one time. HYM = Hymenophyllaceae; T = Trichomanes s.l.; H = Hymenophyllum s.l.; nomenclature follows Morton (1968) with his sectional names (see Table 1 ) provided in parentheses

Although we have yet to take into account the affinities of two additional problematic and monotypic filmy fern genera, Rosenstockia and Hymenoglossum, both of which are considered by most authors to be more closely related to Hymenophyllum s.l. than to Trichomanes s.l. (Morton, 1968 ; Pichi Sermolli, 1977 ; Schneider, 1996 ), the monophyly of Hymenophyllum s.l. seems certain. With the possible exception of Cardiomanes, Serpyllopsis, and some species of Microtrichomanes, it mostly includes taxa that lack tubular-based involucres. Because of the reduced sampling and the weak support for most nodes within the Hymenophyllum s.l. group, discussion of relationships therein is not yet possible.

Utility of rbcL for phylogenetic work in Hymenophyllaceae
rbcL sequences provide better resolution within Trichomanes than within Hymenophyllum. The average sequence percentage divergence for taxa within Trichomanes s.l. is 9.80% (uncorrected distances between all possible species pairs calculated across all 1206 nucleotide sites). This is similar to values calculated for intergeneric relationships among diverse fern genera (Wolf, Soltis, and Soltis, 1994 ; Haufler and Ranker, 1995 ), suggesting that subtaxa of Trichomanes conform more closely to other fern genera. The average sequence percentage divergence for taxa within Hymenophyllum s.l. (including Cardiomanes, Microtrichomanes, and Serpyllopsis) is 2.57%. This is in accord with average infrageneric values for ferns (Wolf, Soltis, and Soltis, 1994 ; Haufler and Ranker, 1995 ) and explains the lack of phylogenetic resolution within Hymenophyllum from rbcL data. Future molecular studies focusing on Hymenophyllum will require data from more rapidly evolving gene regions (e.g., chloroplast trnL—trnF: Taberlet et al., 1991 ; nuclear ITS: Baldwin, 1992 ). Explanations for this nearly fourfold difference in relative sequence divergence between the two groups (compare remarkable branch length differences between Hymenophyllum s.l. and Trichomanes s.l. clades in Figs. 4 and 5) might include a more recent diversification of Hymenophyllum as compared to Trichomanes, or slower evolution of rbcL in Hymenophyllum than in Trichomanes. The Hymenophyllum group is more uniform in terms of its morphology and ecological specializations—all species are epiphytic or epilithic. Species in the Trichomanes group are morphologically much more diverse and occupy a greater variety of habitats—terrestrial, lianescent, epilithic, and epiphytic—which might explain, in part, the higher level of molecular divergence observed. Heterogeneity in evolutionary rates for rbcL has been observed in several groups (Wilson, Gaut, and Clegg, 1990 ; Bousquet et al., 1992 ; Gaut et al., 1992 ; Lewis, Mishler, and Vilgalys, 1997 ), but explanations proposed for this phenomenon (including different generation times, influence of population size) have not been convincingly demonstrated. Interpretations for the rbcL heterogeneity observed in filmy ferns are currently under study (K. M. Pryer, A. R. Smith, and J. -Y. Dubuisson, unpublished data).

	CONCLUSIONS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

 
Evidence from rbcL robustly supports two monophyletic groups of filmy ferns, corresponding to the two classical genera Trichomanes s.l. and Hymenophyllum s.l. This basal dichotomy in Hymenophyllaceae requires further confirmation by including two other monotypic genera of dubious affinity, Hymenoglossum and Rosenstockia (not available for this study), as well as a more extended sampling of Microtrichomanes. Hymenophyllum s.l. is here shown to include several small segregate genera, including Cardiomanes, Serpyllopsis, and one species of Microtrichomanes. The conical- or tubular-based involucres that typify Trichomanes s.l. and the most basal taxon in Hymenophyllum s.l., Cardiomanes, are a plesiomorphic character state for Hymenophyllaceae. Tubular-based involucres appearing in other members of Hymenophyllum s.l. are most probably derived independently and more than one time. Bivalved involucres were likely derived a single time within Hymenophyllum s.l.

The chloroplast gene rbcL will likely be useful for further discrimination of various lineages within the Trichomanes group. Conversely, the lack of resolution among taxa within the Hymenophyllum group implies that other genes will be more appropriate in developing an evolutionary hypothesis for relationships among these ferns.

	FOOTNOTES

⁵ Author for reprint requests, current address: Dept. of Biology, Duke University, Durham, NC 27708 USA (e-mail: kpryer{at}fmnh.org ).

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