Tectaria × hongkongensis S.Y. Dong, 2016

Tectaria × hongkongensis S.Y. Dong View in CoL , nothosp. nov. ( Figs. 1 View FIGURE 1 & 2 View FIGURE 2 )

Type:— CHINA. Guangdong: Guangzhou, South China Botanical Garden (Introduced from Kadoorie Farm & Botanic Garden, Hong Kong, natural in Hong Kong), 30 m, 17 Sep 2011, S. Y. Dong 3631 (holotype, IBSC; isotypes, IBSC) .

Rhizome short-creeping, fronds strongly dimorphic. Sterile stipes 5–15 cm long, 1–2 mm thick, dark brown to castaneous, covered with short hairs (consisting of 3–4 cells), with some narrow scales confined to the base of or on lower stipe; scales brown, 4–6 mm long, ca. 0.2–0.5 mm wide, entire; lamina simple or trilobed, 12–22 long, 6–16 cm wide at base, lanceolate or triangular, crenate at margin or variously lobed towards base, cordate at base, obtuse at apex, fully developed fronds with a pair of basal pinnae; basal lobes or pinnae oblong, 4–9 cm long, 1.5–4 cm wide, entire, obtuse at apex, broadly cuneate at base, sessile; veins amply anastomosing, 4–6 veins arising from either side of main lateral veins, connecting, areoles with included free veinlets, veinlets variously directed, mostly branched, their ends thickened; lamina chartaceous or herbaceous when dry, glabrous except sparse minute hairs on either surface of rachis and on abaxial surface of main lateral veins, rachis adaxially flat and abaxially prominent. Fertile fronds much contracted, with much longer stipes to 20–23 cm long; fertile lamina trilobed, with a long central lobe and a short lateral one at base on either side; central lobe 9–10 cm long, 1.5–2 cm wide, distal part gradually narrowed, somewhat suddenly narrowed at base and connected (rarely separate) to lateral lobes; lateral lobes or pinnae obliquely spreading, lanceolate, 3–5 cm long, 3–5 mm wide, crenate or lobed one thirds to rachis, acuminate at apex, adnate to rachis; veins anastomosing, much simpler than those on sterile lamina, areoles lacking included free veinlets; sporangia distributed along connected veins between main lateral veins, sterile space present along either side of main lateral veins and on central part of veins’ areoles, indusia wanting; spores aborted.

Additional specimens examined (paratype):— CHINA. Hong Kong: Kadoorie Farm & Botanic Garden, July 2005, Wicky Lee s.n. ( IBSC).

Distribution:—Currently known natural in Hong Kong, cultivated in some gardens in southern China, such as Fairylake Botanical Garden, Shenzhen, and South China Botanical Garden, Guangzhou.

Reproduction:—We have kept on observing the development of spores since 2005 when the hybrid was initially introduced to South China Botanical Garden (SCBG) from Hong Kong. It can produce fertile fronds several times per year, but the spores seem never developed at all. We can see many sporangia on the abaxial surface of fertile lamina but when examining using lens or microscopes we found that the sporangia are all empty, without any spores developed inside the sporangia ( Fig. 2 View FIGURE 2 : D, E). The originally introduced plant maintains alive all these years in SCBG and can bear new fronds, both sterile and fertile ones, every year on the tip of the creeping rhizome. The branched rhizome can be cut off and grows independently. So the T. × hongkongensis can be determined as a sterile hybrid.

Cytology:—To know the ploidy of Tectaria × hongkongensis we examined the chromosome numbers of somatic cells. Leaf tips were pretreated in 0.002 M 8-hydroxyquinoline solution at room temperature (about 25°C) for 6 h, fixed in 1: 3 acetic-alcohol mixture (one part of glacial acetic acid and three parts of absolute ethanol) at 4°C for 12 h, macerated in 1: 1 mixture of 1 M HCl and 45% acetic acid at 45° for 30 min, and then stained and squashed in 1% aceto-orcein.

The somatic chromosome number of Tectaria × hongkongensis was carried out to be 2 n = 120 ( Fig. 3 View FIGURE 3 ). It is a triploidy since the basic number of Tectaria is determined as x = 40 ( Love et al., 1977; Takamiya, 1996; Cheng & Zhang, 2010). Cytological data provide strong evidence for the hybrid origin of T. × hongkongensis .

Postulated parents:—Morphological comparisons show that Tectaria × hongkongensis is most similar to T. zeilanica ( Houttuyn, 1783: 43) Sledge (1972: 422) , a common species of Tectaria in Hong Kong ( Lee et al., 2003). Both have the strongly dimorphic fronds, creeping rhizomes, similar shape of fertile fronds, acrostichoid or nearly so sporangia. Furthermore, the shape and division of the young or premature sterile fronds in T. × hongkongensis are very similar to the sterile fronds of T. zeilanica . The main differences between the two taxa lay in the fully developed sterile fronds of T. × hongkongensis being much bigger, nearly glabrous, and with a pair of much more prolonged basal lobes or pinnae. Except T. zeilanica , the hybrid does not seem similar to any other species of Tectaria . So T. zeilanica is postulated to be one of parents of T. × hongkongensis and the second parent is unknown to us based on morphology.

Molecular data, however, provide clues on the second parent of Tectaria × hongkongensis . In the molecular tree based on several regions of cpDNA (atpB, ndhF plus ndhF-trnL, rbcL, rps16-matK plus matK, and trnL-F), the sampled T. × hongkongensis (Dong 3631) was resolved as sister to two samples of Hemigramma harlandii (= T. harlandii ) ( Ding et al., 2014). This suggests that T. harlandii is probably the maternal parent of T. × hongkongensis . In the size of plants T. × hongkongensis is intermediate between T. zeilanica and T. harlandii , and the latter two are only species with strongly dimorphic leaves and acrostichoid sori in southern China (including Hong Kong). Cytological data are also in line with the hypothesis that T. × hongkongensis is derived from the hybridization between T. zeilanica and T. harlandii because T. harlandii is tetraploid with n = 80 ( Tsai & Shieh, 1985) whereas T. zeilanica was reported with n = 80 from Sri Lanka ( Manton and Sledge, 1954) and n = 40 from Taiwan ( Tsai and Shieh, 1977, 1985), though we fail to examine the chromosome numbers of both species from Hong Kong. We have also tried to test the phylogenetic relationships between T. × hongkongensis and T. zeilanica using nuclear genes (SAD1, TPLATE, PgiC) but failed due to the inappropriate markers and the difficulty of the sequencing itself. It remains for further studies to confirm the paternal parent of T. × hongkongensis .