Abstract

Introduction

Cryptic species, a common and increasingly used term, refers to taxa that are erroneously classified as a single species due to the paucity of conspicuous morphological differences (Trontelj and Fišer, 2009; Detwiler et al., 2010; Struck et al., 2018). Cryptic species represent a potentially important influence on the accuracy of detailed assessments of biodiversity (Witt et al., 2006; Trontelj and Fišer, 2009) and can lead to novel insights regarding patterns and processes of biodiversity, including geographic variation in species distributions and species coexistence (Fiser et al., 2018). However, cryptic species are seldom considered in biodiversity assessments owing to the lack of affordable and efficient diagnostic methods (Witt et al., 2006). This is compounded by the fact the high rate at which cryptic species are discovered in molecular studies suggests that number of cryptic species is far greater than prior estimates.

Studies on cryptic species throughout the whole tree of life have increased exponentially over the past two decades, fueled in large part by the increasing availability of DNA sequences, which facilitate various genetic approaches to the resolution of cryptic diversity (Sites and Marshall, 2003; Bickford et al., 2007). The prevalence of considerable cryptic diversity has been uncovered in a diverse range of groups, including in plants (Okuyama and Kato, 2009; Carstens and Satler, 2013; Ji et al., 2020; Kinosian et al., 2020; Li et al., 2020) and many animals (Hebert et al., 2004; Oliver et al., 2009; Manthey et al., 2011; Nadler and DE León, 2011; Phiri and Daniels, 2016), suggesting that cryptic species probably represent a significant portion of undiscovered biodiversity (Jörger and Schrödl, 2013; Pante et al., 2015; Loxdale et al., 2016). The ever-increasing cryptic diversity that genetics has resolved poses a taxonomic challenge in terms of what taxonomic ranks should be assigned to cryptic species that can be recognized on a genetic, but not necessarily morphological, basis. One practical proposal has been that the taxonomic ranks of species should be reserved for organisms showing observable morphological variation, while resolved cryptic species should be designated as intraspecific ranks (Maxwell and Dekkers, 2019; Maxwell et al., 2021).

Cryptic species may also be concealed in cases where there is considerable morphological variation but without clear boundaries supporting species delimitation, such as in the fern genus Dicranopteris Bernh. Dicranopteris is one of six genera in Gleicheniaceae (PPG I, 2016), an early-diverging leptosporangiate fern (Schuettpelz and Pryer, 2007; Choo and Escapa, 2018). The genus is unique on the part of its branching and leaf morphology as characterized by a pseudo-dichotomously branched fronds that produces a forking architecture, resulting from abortion or dormancy of the apical bud (Perrie et al., 2007). The unique morphology is attractive by which some species were used as ornamental plants (Marpaung and Susandarini, 2021). Dicranopteris is composed of about 20 species (Schuettpelz et al., 2016) that occur widely in tropical and subtropical areas (Ding et al., 2013). Across its range, Dicranopteris displays an extraordinarily high level of morphological diversity (Figure 1) that is not easily translated into species boundaries. In fact, due to these difficulties, no comprehensive species classification has been proposed for the genus, despite several prior studies based on morphology, sometimes with only regional sampling (Supplementary Table 1).

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FIGURE 1

A selection of species of Dicranopteris. (A) D. pedata. (B) D. linearis. (C) D. ampla. (D) D. tetraphylla. (E) D. inaequalis. (F) D. latiloba. (G) D. subpectinata. (H) D. alternans. (I) D. subspeciosa.

Within Dicranopteris, D. linearis (Burm.f.) Underw. has been particularly taxonomically challenging. D. linearis was divided into 13 varieties in Southeast Asia by Holttum (1959), who admitted that some varieties were more distinct than others and should probably be recognized as species. For example, the four varieties D. linearis var. demota, D. linearis var. tetraphylla, D. linearis var. montana, and D. linearis var. altissima, always possess accessory branches at the bases of their ultimate branches, whereas other varieties are not always present. In addition, these four varieties can be also separated based on other characteristics, such as branches at successive forks alternately being equal or unequal, lower pinnae surfaces bearing some hairs or not, angles of secondary and later forks, and dimensions of the pinnae (Underwood, 1907; Nakai, 1950; Ching et al., 1959; Holttum, 1959; Huang, 1994; Piggott, 1996; Ding et al., 2013). Following Holttum, Ding et al. (2013) recognized D. linearis and its varieties as a single species and placed them under the D. pedata, which likely obscured its real complexity. With these regards, taxonomic revisions on the placement of D. linearis and its varieties into the genus are very dynamic. Nonetheless, several varieties have been reinstated the status of species. A study by Ding et al. (2013) on the genus treated D. linearis var. montana under D. taiwanensis. Similarly, Kuo et al. (2019) in their phylogenetic study of updating Taiwanese pteridophyte checklist provided support for separating Dicranopteris subpectinata (Christ) C.M. Kuo and Dicranopteris tetraphylla (Rosenst.) C.M. Kuo of Taiwan from D. linearis.

Due to the diverse morphology and complex taxonomic history of Dicranopteris (Supplementary Table 1), we suspected that there may be a large number of cryptic species in this genus. Therefore, we sought to apply molecular phylogeny as a complement to morphology to resolve its species boundaries. To accomplish this, we incorporated 13 taxa, representing well over half of the known diversity in Dicranopteris, and five plastid DNA regions (rbcL, atpB, matK, rps4, and trnL-trnF). Specifically, our aims were to: (1) resolve phylogenetic relationships in Dicranopteris, especially among the varieties of D. linearis, (2) provide a preliminary revised taxonomy of Dicranopteris on the basis of molecular phylogeny and morphological characters, and (3) uncover cryptic diversity in the genus if present.

Materials and Methods

Results

Phylogenetic Relationships Within Dicranopteris

In order to reveal the phylogenetic relationships between nine species of Dicranopteris along with its four varieties, a molecular phylogenetic analysis was performed based on five DNA regions. The concatenated cpDNA sequences yielded an aligned data matrix 3,430 bp long. Phylogenetic analyses using BI, ML, and MP showed that Dicranopteris comprises 10 highly supported clades (Figure 2 and Supplementary Figures 1, 2). Accessions of widely accepted species of Dicranopteris, D. ampla, and D. pedata, formed well-resolved clades (BIPP = 0.99, MLBS = 96%, and MPBS = 96%; BIPP = 0.99, MLBS = 98%, and MPBS = 96%; respectively). Moreover, D. gigantea and D. curranii, collected from Hainan Island of China (HNS065 and HNS082) as well as Thailand (ZXL09776) and Malaysia (SG1685) formed a clade (BIPP = 1.0, MLBS = 98%, and MPBS = 98%) (Figure 2 and Supplementary Figures 1, 2). The analyses revealed that D. linearis was polyphyletic with several varieties clustered with other species of forked ferns (Figure 2 and Supplementary Figures 1, 2). Notably, accessions of D. linearis from southern China formed a clade that was strongly supported as a sister to D. linearis from Malaysia and D. taiwanensis (BIPP = 0.99, MLBS = 79%, and MPBS = 77%). Additionally, a species similar to that of D. curranii formed a highly supported (BIPP = 1.0, MLBS = 92%, and MPBS = 99%), which has a range within the Indochina Peninsula (Figure 2 and Supplementary Figures 1, 2).

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FIGURE 2

It showing phylogeny and the main morphological diagnostic features of Dicranopteris (drawn by LJC). (A) ML tree of Dicranopteris based on the concatenation of rbcL, atpB, rps4, matK, and trnL-trnF. Numbers above each branch are support values in the order of posterior probability from Bayesian analysis (BIPP), bootstrap percentages of maximum likelihood analysis (MLBS), and bootstrap percentages of maximum parsimony (MPBS). The dash (-) indicates a node with BIPP < 0.9, MLBS < 70%, MPBS < 70%. (B) A latend bud with stipule-like pseudostipules always presents at the primary fork and ultimate fork. (C) The primary fork with terminal dormant buds and stipule-like pseudostipules. (D) The primary fork with a sterile bud. (E) Lateral branches forked more than three times and alternate unequal forking. (F) Lateral branches forked more than three times and without accessory branch.

Divergence Time Estimation

Our divergence time estimations indicated that Dicranopteris evolved ca. 213.04 Mya [95% highest posterior density (HPD): 154.65–264.09 Mya] (Figure 3). The stem age of Dicranopteris was estimated to be approximately 167.65 Mya (95% HPD: 104.25–238.95 Mya) (Figure 3). Dicranopteris diversified considerably from the Paleocene to Miocene (84.33–9.99 Mya) (Figure 3), and many varieties of D. linearis originated during that time.

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FIGURE 3

Chronogram presenting estimated divergence times using BEAST based on the concatenated rbcL, atpB, rps4, trnL-trnF, and matK dataset. Numbers above/under the tree branches represented median ages and 95% highest posterior density (HPD) intervals. Break stars indicated the calibrating points.

Discussion

Hidden Cryptic Biodiversity in Dicranopteris

Evolutionary stasis is common for ancient lineages (Bomfleur et al., 2014; Jin et al., 2020; Wei et al., 2021), such as ferns. Accordingly, cryptic species may be particularly prevalent among these lineages due to extensive phenotypic plasticity, often resulting in extreme difficulty in classifying old taxa (Li et al., 2020). In this study, we found that the main extant lineages of Dicranopteris were ancient (Figure 3), which is consistent with the cryptic diversity in the genus that we detected as well as ongoing taxonomic difficulties. Compounding the problem is that Dicranopteris may have experienced flourishing diversification during the Paleocene to the Micoene (Schneider et al., 2004; Schuettpelz and Pryer, 2007; Sundue et al., 2015; Figures 2, ​,33 and Supplementary Figure 1), and this can also lead to subsequent taxonomic confusion.

Recently, Marpaung and Susandarini (2021) investigated the variation on morphology and spore characters among two species and seven varieties of Dicranopteris. The result revealed that the genus has high morphological variations, as indicated by the presence of intraspecific categories. In the present study, we further used molecular data as complementary to morphology to explore cryptic biodiversity in Dicranopteris. We were able to phylogenetically and morphologically differentiate two new species (Figures 2, ​,4),4), D. austrosinensis sp. nov. and D. baliensis sp. nov., and resolve several previously unsettled aspects of species classification of Dicranopteris, including five new combinations. In addition, the species D. pedata recorded in Flora of China (Ding et al., 2013) was proved to hide cryptic species. Specifically, the current treatment of D. pedata in Flora of China consists of three species, D. linearis, D. austrosinensis sp. nov., and D. pedata s. str. Among the three species, only D. austrosinensis sp. nov. presents a pair of accessory branches at the ultimate branches. D. linearis differs from the similar D. pedata by having more basal inner segments of ultimate pinnules shortened. Overall, we have preliminarily revealed that Dicranopteris likely harbors a large constellation of cryptic diversity (Figure 2 and Supplementary Figures 1, 2).

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FIGURE 4

It showing two new species and similar species. (A) D. austrosinensis sp. nov. (B) The main fork of D. austrosinensis sp. nov. showing a latend bud with stipule-like pseudostipules. (C) D. taiwanensis. (D) The main fork of D. taiwanensis showing sterile bud. (E) The type specimen of D. austrosinensis sp. nov. (F) D. baliensis sp. nov. (G) Crozier of D. baliensis sp. nov. with red–brown scales. (H) Lower surface of costae and costules of D. baliensis sp. nov. with rather persistent hairs. (I) D. curranii. (J) Crozier of D. curranii with atrocastaneous scales. (K) Lower surface of costae and costules of D. curranii with deciduous hairs. (L) The type specimen of D. baliensis sp. nov.

Conclusion

The present study represented the first comprehensive molecular phylogenetic analysis of Dicranopteris and, therefore, provided additional insights on the Gleicheniaceae tree of life. On the basis of our molecular phylogeny from cpDNA and morphological evidence, we showed that Dicranopteris hides considerable cryptic diversity, and we were able to disentangle two new cryptic species, D. austrosinensis sp. nov. and D. baliensis sp. nov., from the diverse species complex, D. linearis. We also clarified the previously unsettled status of five taxa in Dicranopteris and, thus, proposed new combinations. We found that Dicranopteris evolved 213.04 Mya and underwent a flourishing diversification during the Miocene leading to much of its extant diversity. Our study highlighted the importance of applying morphology and molecular data to resolve relationships within taxonomically recalcitrant genera and seek out cryptic diversity. Within Dicranopteris, our results probably represented only the “tip of the iceberg” in terms of cryptic diversity, and much more intensive sampling is critical in future studies.

Taxonomic Treatment

• (1)

  Dicranopteris austrosinensis Y.H.Yan & Z.Y.Wei, sp. nov.

Type: —CHINA, Hong Kong, Mt. Parker, October 26, 2010, Hong Kong Fern Survey Team E016 (holotype, CSH).

Diagnosis: —The new species is similar to Dicranopteris taiwanensis in having a pair of accessory branches at ultimate branches, while it differs in the main forks presenting a latent bud with two lobed pseudostipules.

Description: —Plants terrestrial, about 1.5 m tall. Rhizome creeping, (2–)3–5 mm thick, covered with dense ferrugineous hairs. Rachis dark brown, glabrous, 0.7–1 m long, 2–6 mm thick, 4–5 times dichotomously branched, forking in lateral branch–systems alternately unequal, fractiflex, with a pair of lateral stipule-like pinnules at each dichotomy except for the primary branch, basal internode 7–10 cm, second internode slightly shorter, 6–7 cm long, ultimate internode shortest, usually 4–5 cm long. Dormant buds ovate, ca. 4–8 × 5–10 mm, covered with brown hairs, subtending pseudostipules small, lanceolate with rounded bases, margin irregularly triangular. Pinnae 4–5 forked, lanceolate or broadly lanceolate, a pair of lateral pinnae at each dichotomy lanceolate shorter, 8–12 cm long and 4–6 cm wide, rest pair of pinnae large, 3–4 × 13–16 cm, base and apex attenuate, abaxially glabrous and pale, yellowish green or green adaxially, 2–3 pairs of basal segments decrescent. Segments 2–3 cm, 20–35 pairs, oblong to cylindrical, apex truncate, adaxially glabrous, the veins 2–3 forked. Sori inframedial, 1 line on each side of costule, 8–10 sporangia per sorus.

Additional Specimens Examined: —China. Guangdong Province. Shenzhen City, Dapeng New District, Yangmeikeng, 16 August 2020, Yan Y.H. et al. YYH15634 (NOCC); Gaoyao City, 1 August 1932, Lau S.Y. 20333 (PE); Zhaoqing City, Deqing District, 16 July 1958, Liu H.G. 00904 (PE). Hainan Province. Changjiang Li Autonomous County, Bawangling, 4 April 2002, Chen Z.C. 010796 (SZG). Hong Kong. 27 September 2002, Yan Y.H. 665 (IBSC). Guangxi Province. Guangxi Zhuang Autonomous Region, Fangkonggang City, Fangcheng District, Nawan mountain, 14 August 2010, Xie Y.J. & Liang S.Z. B0822 (IBK). Guizhou Province. Qiannan Buyi and Miao Autonomous Prefecture, Libo District, 27 April 2015, Zhang X.C., Guo Z.Y. & Xiang Q.P. 7297 (PE). Vietnam. Mount Tai Hoang Mao, 30 July 1939, Tseng H.T. 29363 (HITBC, photo!).

Distribution and ecology: —It forms dense colonies in open habitats in montane forests, thickets and forest margins, at ca. 50–500 m. Mainly occurring in South China (Guangxi, Guangdong, Hainan, Hong Kong, Guizhou) and Vietnam.

• (2)

  Dicranopteris baliensis Y.H.Yan & Z.Y.Wei sp. nov.

Type: —Indonesia, Bali Island, September 29, 2014, Yan Y.H. & Shang H. INA-BL58 (holotype, CSH).

Diagnosis: —The new species is similar to Dicranopteris curranii with large fronds, rachis 2 or 3 times dichotomously branched, and sori in 1 line on each side of costule, but differs in lower surface of costae and costules densely hairy, red–brown, and persistently.

Description: —Plants terrestrial, 1–1.5 m tall. Rhizome creeping. Rachis stamineous, moderately brown scales, ca. 30–50 cm long between pinnae, 2 or 3 times dichotomously branched, primary rachis-branches almost equally forked, first branch 2.5–3.8 cm long and 1.0–1.8 mm wide, second branch shorter, 1.8–2.2 cm long and 0.8–1.0 mm wide, opposite branches of equal length, accessory branches at each dichotomy except for the ultimate branch, distal branches with overlapping segments. Rachis buds covered with short and usually concolorous red–brown scales. Dormant buds ovate, ca. 3–5 × 8–10 mm, covered with dense red–brown hairs, pseudostipules lanceolate. Pinnae lanceolate, generally large, ultimate pinnae longest, 25–30 cm long, 8–10 cm wide, basal pairs of segments slightly narrowed, apex acuminate, 7–8 pairs of distal segments decussate, with red–brown hairs abaxially. Segments 50–52 pairs, 2.2–3 cm long, 4.1–6.8 mm wide, distal and medial pairs of segments largest, the veins 2–3 forked. Sori inframedial, 1 line on each side of costule, 12–14 sporangia per sorus.

Additional Specimens Examined: —Indonesia. Bali Island, September 29, 2014, Yan Y.H. & Shang H. INA-BL62 (CSH).

Distribution and ecology: —Terrestrial in thickets, forest, forest margins. Endemic to montane forests in Indonesia (Bali Island).

Key to Dicranopteris Species of Asia

• 1a.

  Ultimate forks with a pair of accessory branches …………..2

• 1b.

  Ultimate forks without a pair of accessory branches………4

• 2a.

  Main fork presenting a sterile bud without pseudostipules………………………………………….. D. taiwanensis

• 2b.

  Main fork showing a latent bud with two pseudostipules…………………………………………………………………3

• 3a.

  Leaves leathery, latent bud with two pinnatifid pseudostipules at mainforks ………………………. D. tetraphylla

• 3b.

  Leaves papery, latent bud with two lobed pseudostipules at main forks …………………………………………….. D. austrosinensis

• 4a.

  Lateral branches at each fork approximately equal; ultimate pinnae 10-15 cm wide …………………………………………………… 5

• 4b.

  Lateral branches at each fork alternately unequal; ultimate pinnule 3-6 cm wide ……………………………………………………… 7

• 5a.

  Lower surface of costae and costules glabrous……….. D. ampla

• 5b.

  Lower surface of costae and costules hairy……………………..6

• 6a.

  Lower surface of costae and costules sparsely hairy, brown, deciduously…………………………………………………….D. curranii

• 6b.

  Lower surface of costae and costules densely hairy, red-brown, persistently…………………………………………D. baliensis

• 7a.

  Lateral branches forked 1-3 times…………………………………8

• 7b.

  Lateral branches forked more than 3 times………………….10

• 8a.

  Angle of ultimate fork approximately a right angle………………………………………………………………D. latiloba

• 8b.

  Angle of ultimate fork usually less than 60°……………………9

• 9a.

  Ultimate branches with only 3-4 basal internal segments gradually reduced………………………………………….D. pedata

• 9b.

  Ultimate branches with approximately 10 basal internal segments gradually reduced………………………………D. linearis

• 10a.

  Lower surface glabrous…………………………….D. subpectinata

• 10b.

  Lower surface covered with hairs…………………………………11

• 11a.

  Lower surface of lamina segments with red-brown hairs…………………………………………………………….D. alternans

• 11b.

  Lower surface of lamina segments with pale hairs………….12

• 12a.

  Angle of the secondary and later rachis forking not more than a right angle…………………………………………D. subspeciosa

• 12b.

  Angle of the secondary and later rachis forking more than a right angle…………………………………………………..D. inaequalis

Data Availability Statement

The datasets presented in this study can be found in online repositories. The names of the repository/repositories and accession number(s) can be found in the article/Supplementary Material.

Author Contributions

ZYW and YHY designed the experiments. ZYW, ZQX, and JPS performed the research. HS, XLZ, WX, BA, and YHY collected the materials. ZYW and ZQX analyzed the data. ZYW and LJC drew the figures and wrote the draft. QY processed the figures. YHY, SM, and JGC revised the draft. All authors contributed to the article and approved the submitted version.

Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s Note

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Acknowledgments

References