A new species of Sedum (Crassulaceae) from Mount Danxia in Guangdong, China

Yan-Shuang Huang; Kai-Kai Meng; Yuan-Yuan Sun; Zai-Xiong Chen; Qiang Fan

doi:10.3897/phytokeys.221.97495

Abstract

Sedum jinglanii, a new species of Crassulaceae from Mount Danxia in Guangdong, China, is described and illustrated. Phylogenetic analysis based on the internal transcribed spacer (ITS) region of nrDNA suggests that the new species belongs to S. sect. Sedum sensu Fu and Ohba (2001) in the “Flora of China”, and is sister to a clade comprising S. alfredi and S. emarginatum with high support values (SH-aLRT = 84, UFBS = 95) but is distantly related to S. baileyi. The new species is morphologically similar to S. alfredi but it can be distinguished from the latter in its opposite leaves (vs. alternate leaves), its usually wider leaves (0.4–1.2 cm vs. 0.2–0.6 cm), its usually shorter petals (3.4–4.5 mm vs. 4–6 mm), its shorter nectar scales (0.4–0.5 mm vs. 0.5–1 mm), its shorter carpels (1.5–2.6 mm vs. 4–5 mm), and its shorter styles (0.6–0.9 mm vs. 1–2 mm). The new species can be easily distinguished from S. emarginatum which both have opposite leaves by its short, erect or ascending rhizome (vs. long and prostrate rhizome in the latter), shorter petals (3.4–4.5 mm vs. 6–8 mm) and shorter carpels (1.5–2.6 mm vs. 4–5 mm). It can also be easily distinguished from S. baileyi by its short, erect or ascending rhizome (vs. long and prostrate rhizome) and its shorter style (0.6–0.9 mm vs. 1–1.5 mm).

Keywords

Danxia landscape, morphology, nrITS, Sedum sect. Sedum

Introduction

According to Fu and Ohba (2001) in the “Flora of China”, Sedum Linnaeus is the most species-rich genus of the family Crassulaceae, comprising about 470 species. However, as presently circumscribed, the genus is highly polyphyletic, and a monophyletic circumscribed genus Sedum s.l. would comprise approximately 755 species by inclusion of all 14 genera currently recognized in tribe Sedeae into it (Messerschmid et al. 2020). The genus is distributed in temperate and subtropical environments, and the diversity center is in the Mediterranean Sea, Central America, the Himalayas and East Asia (Stephenson 1994; Thiede and Eggli 2007). In China, 121 Sedum species are documented, amongst which 91 species are endemic (Fu and Ohba 2001).

During the past 20 years, about seventeen Sedum species have been newly described from China, including S. hoi X.F.Jin & B.Y.Ding (Wang et al. 2005), S. plumbizincicola X.H.Guo & S.B.Zhou (Wu et al. 2012), S. fanjingshanense C.D.Yang & X.Yu Wang (Yang et al. 2012), S. kuntsunianum X.F.Jin, S.H.Jin & B.Y.Ding (Jin et al. 2013), S. tarokoense H.W.Lin & J.C.Wang (Lu et al. 2013), S. spiralifolium D.Q.Wang, D.M.Xie & L.Q.Huang (Xie et al. 2014), S. peltatum M.L.Chen & X.H.Cao (Chen et al. 2017), S. kwanwuense H.W.Lin, J.C.Wang & C.T.Lu and S. taiwanalpinum H.W.Lin, J.C.Wang & C.T.Lu (Lu et al. 2019), S. ichangense Y.B.Wang (Wang and Xiong 2019), S. lipingense R.B.Zhang, D.Tan & R.X.Wei (Zhang et al. 2019), S. nanlingense Yan Liu & C.Y.Zou (Zou et al. 2020), S. cirenianum S.S.Ying, S. shaoakouense S.S.Ying and S. shengkuangense S.S.Ying (Ying 2022a), and S. parviflorum S.S.Ying and S. tachingshuianum S.S.Ying (Ying 2022b).

Molecular data unambiguously demonstrate the polyphyletic nature of Sedum with its species placed in four major crown clades of the crassulacean tree, for example, Acre, Aeonium, Leucosedum, and Sempervivum. There is no agreement between specialists regarding the infrageneric structure of Sedum (reviewed in Nikulin et al. 2016). According to Fu and Ohba (2001), Chinese Sedum are divided into three sections, including S. sect. Sedum, S. sect. Oreades (Fröderström) K.T. Fu, and S. sect. Filipes (Fröderström) S.H. Fu. S. sect. Sedum is distinguishable from the two latter sections by the adaxially gibbous carpels and follicles, while S. sect. Oreades differs from S. sect. Filipes in the spurred leaf base and yellow petals (vs. spurless leaf base and white or reddish-purple petals) (Fu and Ohba 2001). During our investigations in Danxiashan National Park, Guangdong Province, China, an unknown Sedum species with opposite leaves was collected. After several years of field observations, comprehensive literature studies and molecular analysis, we confirmed that it was a new species and it is described and illustrated here.

Materials and method

Field investigations and observations were conducted during the ﬂowering and fruiting periods of the putative new species. We obtained morphological data of this putative species by measurements based on 6–8 living samples. Mean values of these statistical data were calculated and then were compared with six other related species (Table 2). The specimens were collected in Danxiashan National Park, Renhua County, Guangdong Province, China. Voucher specimens were deposited in the herbarium of Sun Yat-sen University (SYS).

Two representative individuals from different populations were selected for further molecular experiments, one from Bazhai of Mount Danxia (Y. S. Huang 21040301) and another one from Yanyan of Mount Danxia (Q. Fan et al. DNPC 2873). Fresh leaves of the two individuals were collected and stored with silica gel in zip-lock plastic bags until use. Total DNA was extracted using the modified CTAB method (Doyle and Doyle 1987). The region of the partial internal transcribed spacer 1, 5.8S ribosomal RNA gene and partial internal transcribed spacer 2 was amplified using previously reported primers ITS1 and ITS4 (White et al. 1990). PCR amplifications were performed following Huang et al. (2021).

In order to explore the phylogenetic position of the putative new species in Sedum, ITS sequences of 56 accessions representing 46 Sedum taxa and three outgroup species (Aeonium lancerottense, Aeonium viscatum, and Greenovia aizoon) were downloaded from the Genbank public database at the National Center for Biotechnology Information (NCBI) (Table 1). The sequences were aligned using ClustalW 1.8 (Thompson et al. 1994) and then adjusted manually. Besides, to improve the credibility, we also aligned the sequences using MAFFT v.7.402 (Katoh and Standley 2013), and the alignments generated from the two methods were consistent. The best-fit nucleotide substitution model was determined by ModelFinder (Kalyaanamoorthy et al. 2017). Based on the maximum likelihood (ML) method, the phylogenetic tree was constructed using IQ-Tree v. 2.0.3 (Nguyen et al. 2015) by executing 5,000 replicates of SH approximate likelihood ratio test (SH-aLRT) and ultrafast bootstrap (UFBS) (Hoang et al. 2018). Finally, the tree file was visualized by the online tool of Interactive Tree Of Life (iTOL) v5 (Letunic and Bork 2021).

Table 1.

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Taxa, voucher information, and GenBank accession numbers of the sequences used in this study.

Taxon	Voucher	Accession numbers	References
Sedum Sect. Oreades
S. oreades	Rao 090803-03	KF113733	Zhang et al. 2014
S. trullipetalum	Miyamoto et al. 9420132	AB088630	Mayuzumi and Ohba 2004
S. bergeri	Ni et al.	AY352897	Ni et al. unpublished
S. erici-magnusii	Ito 2077	LC229235	Ito et al. 2017a
Sedum Sect. Sedum
S. jinglanii	Huang 21040301	OP288035	This study
S. jinglanii	Fan et al. DNPC 2873	OQ162326	This study
S. actinocarpum	Ito 1749	LC229265	Ito et al. 2017a
S. alfredi	Kokubugata 17190	AB930259	Ito et al. 2014a
	Kokubugata 17191	AB930260	Ito et al. 2014a
	Kokubugata 17192	AB930261	Ito et al. 2014a
	WUK415208	FJ919953	Wang and Shu unpublished
S. baileyi	LBG0064555	FJ919935	Wang and Shu unpublished
S. bulbiferum	Ito 416	LC229234	Ito et al. 2017a
	130514hs41	KM111166	Xie et al. 2014
	130524qz09	KM111165	Xie et al. 2014
S. emarginatum	130512hs27	KM111145	Xie et al. 2014
S. erythrospermum	Tsutsumi 1504	AB906473	Ito et al. 2014b
S. formosanum	Ito 1260	LC229279	Ito et al. 2017a
S. hakonense	Mayuzumi C00005	AB088625	Mayuzumi and Ohba 2004
S. hangzhouense	Ito 2604	LC260130	Ito et al. 2017b
S. japonicum	Kokubugata 16749	AB906475	Ito et al. 2014b
S. senanense	Ito 2200	LC229238	Ito et al. 2017a
S. oryzifolium	Ito 2285	LC229239	Ito et al. 2017a
S. japonicum var. pumilum	Ito 2287	LC229240	Ito et al. 2017a
S. japonicum ssp. uniflorum	Ito 447	LC229241	Ito et al. 2017a
S. boninense	Ito 2371	LC229242	Ito et al. 2017a
S. jiulungshanense	Ito 76	LC229243	Ito et al. 2017a
S. kiangnanense	CMQ1030	LC229244	Ito et al. 2017a
S. lineare	Mayuzumi C00120	AB088623	Mayuzumi and Ohba 2004
S. lungtsuanense	Ito 3563	LC260131	Ito et al. 2017b
S. makinoi	Kokubugata 16730	AB906476	Ito et al. 2014b
S. morrisonense	Ito 2765	LC229290	Ito et al. 2017a
S. multicaule	Miyamoto et al. TI9596136	AB088631	Mayuzumi and Ohba 2004
S. nagasakianum	Ito 2064	LC229249	Ito et al. 2017a
S. nokoense	Kokubugata 10426	AB906478	Ito et al. 2014b
S. oligospermum	Ito 74	LC229250	Ito et al. 2017a
S. yabeanum	Ito 396	AB906490	Ito et al. 2014b
S. polytrichoides var. setouchiense	Ito 2298	LC229253	Ito et al. 2017a
S. polytrichoides	CMQ1057	LC229251	Ito et al. 2017a
S. rupifragum	Ito 2070	LC229254	Ito et al. 2017a
S. sarmentosum	Ito 978	LC229255	Ito et al. 2017a
S. satumense	Ito 2295	LC229256	Ito et al. 2017a
S. subtile	Shimizu 1999	AB088622	Mayuzumi and Ohba 2004
S. subtile	Ito 2259	LC229257	Ito et al. 2017a
S. subtile	Ito 624	AB930277	Ito et al. 2014a
S. taiwanianum	Ito 2770	LC229297	Ito et al. 2017a
S. tetractinum	Ito 3623	LC260135	Ito et al. 2017b
S. tianmushanense	Ito 355	LC229261	Ito et al. 2017a
S. tosaense	Kokubugata 16726	AB906483	Ito et al. 2014b
S. triactina	9596091	AB088629	Mayuzumi and Ohba 2004
S. tricarpum	Ito 2269	LC229259	Ito et al. 2017a
S. lipingense^*	ZRB1479	MN150061	Zhang et al. 2019
S. mexicanum^*	Ito 647	LC229247	Ito et al. 2017a
S. truncatistigmum^*	Ito 3254	LC229306	Ito et al. 2017a
S. zentaro-tashiroi^*	Ohba 1998	AB088619	Mayuzumi and Ohba 2004
Outgroups
Aeonium lancerottense	Mort 1518	AY082143	Mort et al. 2002
Aeonium viscatum	Mort 1432	AY082154	Mort et al. 2002
Greenovia aizoon	Mort 1425	AY082112	Mort et al. 2002

Results and discussion

The alignment length of the ITS sequences was 624 bp, amongst which 340 were parsimony-informative. Within the new species, only one variable site was detected, but 40 variable sites were detected between the new species and S. alfredi and 40 variable sites were detected between the new species and S. emarginatum, indicating that pronounced genetic differentiation existed between the new species and S. alfredi as well as S. emarginatum. The best-fit nucleotide substitution model was estimated as SYM+I+G4 according to the Bayesian Information Criterion (BIC).

As the ML phylogenetic tree shows (Fig. 1), seven subclades were resolved with moderate to high support values. Accessions of the putative new species, S. alfredi, S. emarginatum, and S. lungtsuanense together formed subclade 7 with high support values (SH-aLRT = 92, UFBS = 98), all belonging to S. sect. Sedum sensu Fu and Ohba (2001).

Figure 1.

Maximum Likelihood tree based on ITS sequences for Eastern Asian species of Sedum sect. Sedum, four species of S. sect. Oreades, and three outgroups. Numbers near the branches are SH approximate likelihood ratio test (SH-aLRT) and ultrafast bootstrap (UFBS) support values. The new species is highlighted in bold.

Morphologically, the putative new species is similar to S. alfredi from which it can be easily distinguished by its opposite leaves (vs. alternate leaves in the latter). Furthermore, the leaves of the putative new species are usually wider than those of S. alfredi (0.4–1.2 mm vs. 0.2–0.6 mm), the petals are usually shorter (3.4–4.5 mm vs. 4–6 mm), the nectar scales shorter (0.4–0.5 mm vs. 0.5–1 mm), the carpels shorter (1.5–2.6 mm vs. 4–5 mm) and the styles shorter (0.6–0.9 mm vs. 1–2 mm) (Table 2). Phylogenetically, the putative new species is closely related to S. emarginatum. Although the leaves of both species are opposite, it can be easily distinguished from the latter by its short, erect or ascending rhizome (vs. long and prostrate rhizome), shorter petals (3.4–4.5 mm vs. 6–8 mm) and shorter carpels (1.5–2.6 mm vs. 4–5 mm). The putative new species was distantly related to S. baileyi in the phylogenetic tree although both are morphologically similar (Table 2). Also, it can be easily distinguished from the latter by its short, erect or ascending rhizome (vs. long and prostrate rhizome) and its shorter style (0.6–0.9 mm vs. 1–1.5 mm).

Table 2.

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Morphological comparisons between S. jinglanii, S. alfredi, S. baileyi, S. emarginatum, S. kuntsunianum, S. makinoi, and S. satumense.

Characters	S. jinglanii	S. alfredi ^†	S. baileyi ^‡	S. emarginatum ^§	S. kuntsunianum ^\|	S. makinoi ^¶	S. satumense ^#
Leaf blade	Spatulate or obovate	Linear-cuneate, spatulate or obovate	Obovate-spatulate	Spatulate-obovate to broadly obovate	Widely obovate or suborbiculate, spatulate	Obovate or obovate-spatulate	Narrowly obovate or spatulate
Leaf size (cm)	0.8–2.9 × 0.4–1.2	1.2–3.0 × 0.2–0.6	1–2.5 × 0.6–0.8	1–2.5 × 0.5–1.2	1.4–2.0 × 0.9–1.5	1–2 × 0.6–0.8	1.0–2.2 × 0.6–0.9
Phyllotaxy	Opposite	Alternate	Opposite	Opposite	Opposite, or rarely alternate at base	Opposite	Opposite
Rhizome	Short, erect or ascending	Short, erect or ascending	Long, prostrate	Long, prostrate	Absent	Short, erect or ascending	Short, erect or ascending
Sepal length (mm)	2–3.1	2–5	1.5–2.5	2–5	5–9	2–3	6–7
Petal length (mm)	3.4–4.5	4–6	4–5	6–8	7–8	4–5	7–8
Stamen length (antepetalous) (mm)	2.2–2.6	2.5–3.5	2–3	3–4	ca. 5	2.5–3.2	–
Stamen length (antesepalous) (mm)	3.2–3.3	3.8–4.5	3–4	4–5	ca. 6	2.8–4.5	–
Nectar scale length (mm)	0.4–0.5	0.5–1	0.4–0.6	0.6–0.8	ca. 0.5	0.5–0.7	ca. 0.5
Carpel length (mm)	1.5–2.6	4–5	2–3	4–5	ca. 5	4–5	–
Style length (mm)	0.6–0.9	1–2	1–1.5	1.5–2	ca. 1	1–2	1.0–1.5

Additionally, four representatives of Sedum sect. Oreades sensu Fu and Ohba (2001) (S. oreades, S. trullipetalum, S. bergeri, and S. erici-magnusii) were also included in our analysis. However, these four species were nested within species belonging to S. sect. Sedum sensu Fu and Ohba (2001), thus showing that S. sect. Sedum might not be monophyletic. This result is consistent with previous studies (Nikulin et al. 2016; Zhang et al. 2019; Messerschmid et al. 2020).

Through numerous scientific investigations, more than a dozen new species were found on Mount Danxia in Guangdong in recent years, and most are endemic to it such as Lespedeza danxiaensis Q.Fan, W.Y.Zhao & K.W.Jiang (Zhao et al. 2021), Asplenium danxiaense K.W.Xu (Xu et al. 2022), Pilea danxiaensis L.F.Fu, A.K.Monro & Y.G.Wei (Fu et al. 2022), Wikstroemia fragrans W.B.Liao, Q.Fan & J.R.Chen (Chen et al. 2022), and Commelina danxiaensis Q.Fan, Long Y.Wang & W.Guo (Wang et al. 2023). As a World Heritage site and tourist attraction, Danxia landform possesses special and complicated habitat differences at a small scale, which might contribute to the plant endemism at Mount Danxia (Peng et al. 2018).

Taxonomic treatment

Sedum jinglanii Yan S.Huang & Q.Fan, sp. nov.

urn:lsid:ipni.org:names:77315511-1

景兰景天

Type

China. Guangdong Province, Renhua County, Mount Danxia, Bazhai, in the cliff of steep slopes, 25°00'N, 113°39'E, 520 m a.s.l., 3 April 2021, Y. S. Huang 21040301 (holotype: SYS; isotype: SYS) (Figs 2, 3).

Figure 2.

Sedum jinglanii sp. nov. A habit B flower with sepals, petals, stamens and carpels C petals and stamens D sepal E leaves. Illustration by Yuan-Yuan Sun based on living field-collected material (Y. S. Huang 21040301).

Figure 3.

Sedum jinglanii sp. nov. A habit B flower, front view, showing brownish-red anthers C carpels and a nectar scale (red arrow) D abaxial leaf surface E young unripe fruits F young sterile individuals A, B, D photographed by Qiang Fan in the field (Pingtouzhai, 6 April 2022, Q. Fan et al., DNPC 1953) C photographed by Min Lin in the lab (7 April 2022, Q. Fan et al., DNPC 1953) E, F photographed by Yan-Shuang Huang (Bazhai, 3 April 2021, Y. S. Huang 21040301).

Diagnosis

This new species is similar to S. alfredi, but differs from the latter in its opposite leaves (vs. alternate leaves), its usually wider leaves (0.8–2.9 × 0.4–1.2 cm vs. 1.2–3.0 × 0.2–0.6 cm), usually shorter petals (3.4–4.5 mm vs. 4–6 mm), shorter nectar scales (0.4–0.5 mm vs. ca. 0.5–1 mm), and shorter carpels (1.5–2.6 mm vs. 4–5 mm). Although the leaves of this new species and of S. emarginatum are opposite, it can be easily distinguished from the latter by its short, erect or ascending rhizomes (vs. long and prostrate rhizomes), shorter petals (3.4–4.5 mm vs. 6–8 mm) and shorter carpels (1.5–2.6 mm vs. 4–5 mm).

Description

Fleshy herbs, perennial; stems glabrous, greenish, often with small reddish dots thus appearing more or less reddish, ascending; leaves opposite, usually deciduous, crowded distally on the stem, succulent; leaf blade spatulate or obovate, 8–29 mm long, 4–12 mm wide, base narrowly cuneate and spurred, apex obtuse and sometimes emarginate; inflorescence in dense terminal cymes, usually two to four branched; bracts leaflike, 1.7–2.4 mm long, 0.7–1.1 mm wide; flowers usually sessile, rarely with short pedicels to 0.8 mm long, unequally 5-merous; sepals green, linear-spatulate, 2–3.1 mm × 0.7–1.4 mm, base shortly spurred; petals yellow, lanceolate to lanceolate-oblong, 3.4–4.5 mm × 0.8–1.1 mm, base connate for 0.1–0.2 mm, apex mucronate; stamens 10, yellow, filiform, arranged in 2 whorls; antesepalous ones 3.2–3.3 mm, antepetalous ones 2.2–2.6 mm; anthers brownish red, long ellipsoid. Nectar scales yellow green, spatulate-quadrangular, 0.4–0.5 × 0.2–0.3 mm, apex obtusely truncate. Carpels yellow green, erect, ovoid-lanceolate, 1.5–2.6 mm long, 0.6–0.9 mm wide, adaxially gibbous, base shortly connate; styles 0.6–0.9 mm long. Follicles yellowish, obliquely divergent. Seeds numerous, brown, oblong, 0.5–0.6 mm, papillate.

Phenology

Flowering from April to May. Fruiting from June to August.

Etymology

Sedum jinglanii is named after Prof. Jing-Lan Feng (1898–1976), an academician of the Chinese Academy of Sciences and one of the founders of mineralogy in China. In 1928, he discovered and named the red beds and related strata in North Guangdong as “Danxia Formation” for the first time (Peng 2020).

Distribution and habitat

Presently, this new species is only known from the type locality, Mount Danxia, Renhua County, Guangdong Province, China. It grows on the cliff of steep slopes at altitudes of 200–550 m a.s.l.

Conservation status

Only five populations were found with no more than 1,000 mature individuals. Thus, the conservation status could be considered as Vulnerable (VU; D1), according to the IUCN Red List Criteria (IUCN Standards and Petitions Subcommittee 2022).

Additional specimens examined

(paratypes). China. Guangdong: Renhua County, Mount Danxia, Pingtouzhai, 25°00'N, 113°37'E, 536 m a.s.l., 6 April 2022, Q. Fan et al., DNPC 1953 (SYS); Renhua County, Mount Danxia, Yanyan, 25°02'N, 113°61'E, 263 m a.s.l., 27 December 2022, Q. Fan et al. DNPC 2873 (SYS).

Acknowledgements

We appreciate Mrs. Jing-Min Dai for her assistance in preparing the manuscript. We thank Prof. Yan-Song Peng from Lushan Botanical Garden, Chinese Academy of Sciences for his help in collecting living material of Sedum baileyi at the type locality. We thank Dr. Bin Chen, senior engineer at Shanghai Chenshan Botanical Garden, Chinese Academy of Sciences for his suggestions in nomenclature. We thank Mrs. Min Lin and Mrs. Li-Juan Liao for their help in the morphological analysis. We also kindly thank Zu-Hao Wang and Wen-Sheng Shu for unpublished sequence data, Yuan-Yuan Sun for the illustration, and the reviewers for their valuable comments. This study was supported by the Guangdong Provincial Special Research Grant for the Creation of National Parks (2021GJGY034) and the Foundation of Administrative Committee of Danxiashan National Park (K22-33000-060, 2016-0293).

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﻿Abstract