Taxonomic Reinstatement of the Endemic Chinese Species Iris thoroldii (Iridaceae) from I. potaninii and Reassessment of I. zhaoana

Iris thoroldii is a perennial herbaceous plant with yellow, blue, or purple flowers. The species is native to the Tibetan Plateau and adjacent areas. In the literature and databases, I. thoroldii has long been treated in synonymy with I. potaninii. Currently, yellow-flowered plants of I. thoroldii are considered I. potanii, and blue-flowered plants are considered I. zhaoana, a replacement name for I. potaninii var. ionantha. This study aimed to clarify the taxonomic identity of I. thoroldii. A critical examination of original material, herbarium specimens, images of living plants, and the literature has shown I. thoroldii to be different from I. potaninii in some previously neglected macromorphological traits and to be conspecific with I. zhaoana. Thus, I. thoroldii is removed here from the synonymy of I. potaninii and accepted as a distinct species. This is endemic to China (central Gansu, Qinghai, and northwestern Sichuan provinces, and also Xinjiang Uygur and Tibet autonomous regions) and reaches the highest elevations compared with all other species in the genus Iris s.l. A revised taxonomy of I. thoroldii is provided, and two color forms, often co-occurring, are accepted: the autonymic yellow-flowered form (including a new synonym I. tigridia var. flavescens for which a lectotype was designated) and a form with blue or purple colors is proposed here, I. thoroldii f. ionantha. In addition, images of type specimens and detailed photographs of living plants for easy identification, along with the list of specimens of I. thoroldii that were examined, and also, comments on its distribution and habitats are provided.


Introduction
Iris L., when considered in a broad sense, is the largest genus of the family Iridaceae distributed in the north temperate zone [1].In China, the genus is represented by approximately 60 species [2,3].In the past five years, each of the in-depth taxonomic studies of Iris have led to changes in the scope of delimitation and systematic positions of the Chinese species (e.g., [4][5][6][7][8][9]).In fact, there are still some species of which very little is known, or where their actual identity is poorly understood.For instance, I. thoroldii Baker is one such species whose identity has long been misinterpreted or even ignored.
When the Kew botanist John Gilbert Baker described I. thoroldii from Tibet, China [10], he mentioned that this plant was distinguished by having curled remnants of leaf bases (Figure 1).A plant with this feature is well known from China under a common name, "Curl-sheath iris", or 卷鞘鸢尾 juan qiao yuanwei in Chinese [2,3,11].
Taxonomically, I. thoroldii has been treated in quite different ways.Only few authors have considered I. thoroldii an independent species (e.g., [12][13][14][15]).Some important remarks with regard to the taxonomy of I. thoroldii were made by Grubov [14].First, he pointed out that I. thoroldii is an endemic species to Chang (or the Tibetan Plateau) and, although closely related to I. tigridia Bunge and I. potaninii Maxim., is readily distinguished by its obtuse, shortly pointed rosette leaves and by its numerous curled coarse-fibered remnants of leaf bases.Second, I. thoroldii is variable in flower color (from pale yellow and yellow, through light and dirty lilac, to purple and dark purple; see Figure 2a-d), and this feature is sometimes observed even within the same clump that consists of plants from different seeds.Grubov concluded that Dykes [16] had erroneously treated I. thoroldii as a synonym of I. potaninii (see also [17][18][19]) and provided evidence for its recognition as an independent species.
Recently, it has been suggested, however, that the plants from western China belon to a species that is different from I. potaninii (sub I. potaninii var.ionantha) [9,48].The tru I. potaninii has non-curled remnants of leaves, and it is found only in southern Siberia Mongolia, and northern China [9].Thus, it has become evident that I. thoroldii is errone Crespo et al. [25] raised I. potaninii var.ionantha to the rank of species as I. zhaoana M.B.Crespo, Alexeeva & Y.E.Xiao.Following Zhao's proposal [20], they assumed that only the purple-flowered plants should be included in this new species.However, Crespo et al. [25] did not realize that the purple-flowered species only occurred in western China; they did not see the original material of I. thoroldii and provisionally included it in I. potaninii, and this issue has not yet been further addressed.As a result, considerable taxonomic confusion remains with regard to the identity of the Tibetan plants to I. potaninii.To date, I. potaninii and I. zhaoana are known to grow together in Tibet as well as in Siberia and Mongolia [26,28,31,[34][35][36]39], with the common name of I. potaninii being "Curl-sheath iris" [34,37,47].
Recently, it has been suggested, however, that the plants from western China belong to a species that is different from I. potaninii (sub I. potaninii var.ionantha) [9,48].The true I. potaninii has non-curled remnants of leaves, and it is found only in southern Siberia, Mongolia, and northern China [9].Thus, it has become evident that I. thoroldii is erroneously synonymized with I. potaninii, as well as the yellow-flowered Tibetan plants are erroneously attributed to I. potaninii, while I. thoroldii is still ignored, and its color forms have not received proper taxonomic treatment.This study aimed to revise the taxonomy of I. thoroldii in order to disentangle the confusion still existing around this name, as described by Baker [10] and determined by its nomenclatural type (Figure 1).The study focuses on the macromorphological characters that are useful for delimiting I. thoroldii and I. potaninii, while the supporting illustrations may facilitate further identification of these species and contribute to the development of identification keys.A critical examination of relevant academic sources, herbarium specimens, and images of living plants, as well as a complete revision of the I. thoroldii nomenclature and analysis of their distribution, have been carried out.

Study Material
The original material of I. thoroldii (Figure 1), I. potaninii (http://re.herbariumle.ru,accessed on 23 October 2023; see Section 4), and I. potaninii var.ionantha (Figure 3) was re-investigated personally.During a visit to the English herbaria in March 2014, a search at K was made for the specimens attributed to the name I. thoroldii, and the type specimen was found (Figure 1).The type specimen of I. potaninii var.ionantha was found at NENU (Figure 3) in May 2019.A herbarium-based study of I. thoroldii was carried out using 35 specimens (Annex 1), available at LE.These specimens belong to the collections of Nikolai Mikhailovich Przhevalsky from his third (1879-1880) and fourth (1883-1885) journeys to Central Asia, the collection of Vsevolod Ivanovich Roborovsky from the Przhevalsky's fourth journey to Central Asia, the collection of Grigory Nikolayevich Potanin from his journey to Gansu Province, China (1883-1886), and the collection of Veniamin Fedorovich Ladygin from the Pyotr Kuzmich Kozlov journey to Tibet (1899-1901).All the specimens are accompanied by labels with the printed note "Nota criticae.V. Grubov" and contain Grubov's handwritten note "Iris Thoroldii Baker, 5 March [19]66" (see https://en.herbariumle.ru/,accessed on 23 October 2023).The herbarium codes are according to Index Herbariorum [49].
Also, more than 200 specimens of I. thoroldii were searched through images available in the databases [50,51], which represent collective data from the Chinese herbaria (BJFC, BNU, HNWP, IBSC, KUN, LZD, NAS, PE, and XJA).The herbarium specimens were identified on the basis of my own experience in dealing with Iris species.A complete list of these specimens is provided in Annex 1.

Morphological Data
In order to clarify the differences between I. thoroldii and I. potaninii, 35 qualitative and quantitative macromorphological characters were selected: (1) rhizome shape, (2) adventitious root shape, (3) rosette leaf shape, (4) rosette leaf apex shape, (5) rosette leaf texture, (6) rosette leaf length (measured from the base to the apex of the longest rosette leaf), (7) rosette leaf width (measured at the broadest part of the broadest rosette leaf), (8) leaf remnants' shape, (9) leaf remnants' height, (10) stem height (measured from the base of the flowering stem to the base of the outer bract), ( 11) number of stem leaves, (12) stem leaf length (measured from the base to the apex of the upper stem leaf), (13) stem leaf shape, (14) number of bracts, (15) bract shape, (16) bract texture, (17) bract length (measured from the base to the apex of the outer bract), (18) pedicel length, (19) perianth tube length (measured from the ovary apex to the base of fall, i.e., outer perianth segment), ( 20) number of flowers, (21) flower color, (22) flower diameter, (23) blade of fall shape, (24) fall length, (25) fall width, (26) standard (i.e., inner perianth segment) shape, (27) standard length, (28) standard width, (29) fruit shape, (30) fruit length, (31) fruit width, (32) seed shape, (33) seed color, (34) seed length, and (35) seed width.The morphological description of I. thoroldii was based on a direct examination of the herbarium specimens from K, LE (Annex 1), and NENU, as well as on the images of well-developed plants in flowering and fruiting stages available in the virtual herbaria [50,51] (Annex 1).I incorporated the morphological data of I. potaninii from a recent study [9] and added information on the leaf remnants' length, number of stem leaves, stem leaf shape, bract shape, flower diameter, and the morphology of fall, standard, and seed obtained as a result of extensive field investigations and thorough examination of specimens from LE and VBGI.The terminology used in the descriptions was based on reference [52].For the seed morphology, the material from the specimen of I. potaninii deposited at LE (Khuvsgul region, Mongolia, 15 km northeast of Urd-daba Pass, 23 July 1972, E. Kukn 248; seeds were measured using an Absolute Digimatic digital caliper, Mitutoyo, Aurora, IL, USA, to an accuracy of 0.1 mm) and an image of I. thoroldii (https://www.cvh.ac.cn/spms/detail.php?id=dd49951a, accessed on 23 October 2023; all were measured using AxioVision, version 4.8 (Carl Zeiss, Oberkochen, Germany)) were used.

Taxonomy and Distribution
Here, the conservative taxonomy of Iris was used [1][2][3]14,16,23,53].For the taxonomy, the Shenzhen Code (hereafter ICN, [54]) was consulted.The International Plant Names Index (hereafter, IPNI [55]) was also consulted for the nomenclature.In the case of disagreement on the infraspecific rank at which a name should be accepted, I followed Brummitt [56].
In the taxonomic treatment section (see below), I extracted the information on distribution of I. thoroldii from the herbarium specimens (see Annex 1) and the databases [28, 35,46] where plants of this species are represented, mainly under the names I. potaninii, I. potaninii var.ionantha, and I. zhaoana.I also used the information provided in reference (sub I. potaninii) [40] (p.289), which is recognized here as a reliable source.

Results
A morphological comparison of I. thoroldii and I. potaninii is presented in Table 1 (also see Table S1 and Figures 2 and 4).Both species share many features, including the following: The rhizome is shortened, weakly branching.Adventitious roots extend from the base of the stem; these are long, with thick upper and thinner lower parts, wrinkled transverse patterns (contractile), few lateral roots, and are yellowish white in color (Figures 2c,d and 4f).Rosette leaves are aggregated in a dense tuft, with the base surrounded by a few papery leaves, narrow-linear, finely ribbed, with waxy coating, and are 0.1-0.5 cm wide.In the wild, the rosette bears straight fibrous remnants of leaf bases, not emerging above ground (Figures 2c,d and 4f).Flowering stems are not emerging above ground; stem leaves are sheath-like and lanceolate, with two bracts, membranous, lanceolate, acute at the apex and without bracteoles.Flowers are solitary, 2-5.5 cm in diameter.Yellow flowers are variable in the color intensity of broken lines of the blade of falls, up to a complete absence of the lines (Figures 2a and 4a-d; also see https://ppbc.iplant.cn/tu/8363242,accessed on 23 October 2023).Flowers are also variable in the shape of falls and standards, having a notch at the apex (emarginate) or being rounded (Figures 2b and 4a-d; also see https://www.inaturalist.org/observations/168065547,accessed on 23 October 2023).The falls have a beard of white, yellow-tipped hairs (Figures 2b and 4a-d); the standards are abruptly narrowed into a narrow claw (Figures 2b and 4b).Fruits are always borne at the soil surface or hidden at the base of rosette leaves and are elliptical, with an obtuse apex and a short beak, which is the proximal part of the dried remnant of the perianth tube (Figures 2g and 4g).Seeds are arillate, brown, glossy, with wrinkled testa (Figures 2h and 4h).Both species often form large colonies or clumps (Figures 2f and 4e).Morphologically, I. thoroldii is distinguished from I. potaninii by its vertical rhizome; by its rosette leaves, which are soft, obtuse, or acute at the apex (Figure 2e) (vs.tough and narrowly acute, Figure 4a); by having longer remnants of leaves, curled after drying (Figures 1 and 3) (vs.always uncurled); by a longer flowering stem, up to 6 cm long (vs. up to 2.5 cm long); by more frequently with 1-2 stem leaves, which are acute at the apex (vs.with three stem leaves that are acuminate); by its bracts being more frequently longer than the perianth tube; by a slightly longer pedicel (vs.extremely short, less than 0.2 cm); by a longer perianth tube; by obovate falls with purple lines (Figure 2a,b) (vs.lingulate falls with brownish lines, Figure 4a-c) and oblanceolate standards (Figure 2b) (vs.obovate, Figure 4c); and by a slightly larger aril (Figure 2h).The variability in the flower color of I. thoroldii can be observed within the same locality (see https://ppbc.iplant.cn/tu/9267464, accessed on 23 October 2023) or even clump (see https://ppbc.iplant.cn/tu/9267465,accessed on 23 October 2023).Thus, a yellow and blue-purple color of flowers is a variation observed only in I. thoroldii, whereas only a yellow color is characteristic of I. potaninii.Morphologically, I. thoroldii is distinguished from I. potaninii by its vertical rhizome; by its rosette leaves, which are soft, obtuse, or acute at the apex (Figure 2e) (vs.tough and narrowly acute, Figure 4a); by having longer remnants of leaves, curled after drying (Figures 1 and 3) (vs.always uncurled); by a longer flowering stem, up to 6 cm long (vs.

Taxonomic Delineation between Iris thoroldii and I. potaninii
Currently, I. thoroldii is treated as a synonym of I. potaninii [26][27][28][29][30][31][32][33][34][35][36][37][38][39].However, the differences between them, listed in Table 1, are sufficient to distinguish I. thoroldii as a distinct species.In particular, the major difference is the shape of the leaf remnants after drying: they are curled in I. thoroldii (Figures 1 and 3) and always straight in I. potaninii.The diagnosis can be made even when using specimens without additional organs (e.g., rhizome, rosette leaves, flowering stem, and seed).Plants with curled remnants of leaves are widespread in the Tibetan Plateau and adjacent areas (central Gansu, Qinghai, and northwestern Sichuan provinces, and also Tibet and Xinjiang Uygur autonomous regions, China; see the Taxonomic Treatment section).Thus, the question as to whether the name I. thoroldii is a synonym of I. potaninii or not has an obvious answer.
Originally, I. potaninii was described in 1880 by Carl Johann Maximowicz from Siberia (Russia) on the basis of the specimens collected by Nikolai Turczaninow from Transbaikal (LE01010785, lectotype [9]; LE01010787, LE01010788, and LE01010790), those collected by Alexander von Bunge from the Charysh River (i.e., Altai Republic; LE01010786 and LE01010789), and Potanin's specimen from Mongolia (LE01011517) [21].After a comprehensive morphological and genetic characterization, it has been placed in the unispecific I. ser.Potaninia Doronkin belonging to I. sect.Psammiris (Spach) J.J.Taylor [9].It is worth noting here that I. potaninii is distributed in steppe patches of the southern Siberian mountain systems in Russia, in northern China (northeastern and western Inner Mongolia, northwestern Heilongjiang Province, and the northern Ningxia Hui Autonomous Region), and in Mongolia at elevations of 550-2800 m [9].
In the journey from Leh (Ladakh Region, India) across Tibet eastward, undertaken by Captain Hamilton Bower in mid-July 1891, William Grant Thorold, Surgeon Captain of the Indian Medical Service, gathered a botanical collection [57].He collected most of the plants in the Tibetan Plateau (or Chang) west and north of Lhasa and found very few of them northeast of Lhasa [10,58].The Thorold's collection was granted to Kew and then treated by William Hemsley [10].Iris thoroldii was described by Baker in Hemsley's study [10] (p.105), but, in fact, the taxonomic history of the species had begun six years before.
During a critical analysis of the literature, I found a name that is overlooked by botanists, I. tigridia var.flavescens Maxim.ex Przew.and informed the IPNI about it.This name was described by Przhevalsky on the basis of the specimens from his fourth journey to Central Asia as follows: "...sinii i palevyi kasatiki ["blue and pale-yellow irises", originally in Russian] (Iris tigridia, I. tigridia var.fluvescens)" [59] (p.163).This collection, gathered from the tectonic depression Qaidam in the northeastern Tibetan Plateau (Haixi Mongol and Tibetan Autonomous Prefecture, Qinghai Province, China) in early June 1884, was treated by Maximowicz, who identified all the plants [59].The specimens of I. tigridia var.flavescens found at LE (LE01071977 and LE01072826; Figure 5) are identical to the original material of I. thoroldii (Figure 1), because these plants are yellow-flowered and have curled remnants of leaves.
However, Thorold's specimen (Figure 1) indicates something that has been overlooked.It is clear that the original material of I. thoroldii represents the same species currently known under the name I. zhaoana (Figure 3).Thus, Baker's name I. thoroldii is reinstated here for the yellow-flowered and blue-flowered Tibetan plants with curled remnants of leaves.As confirmed in the present study, based on an analysis of the herbarium specimens (see Annex 1), images of living plants [28,35], and the literature [14,59,65], some populations of I. thoroldii in the wild are represented by the yellow-flowered form only and are fairly uniform in their coloration, while others are represented by a mixture of the yellow and blue-purple forms.
Moreover, recent molecular data have strongly supported the assumptions that the plants from western China (sub I. potaninii var.ionantha) [9,48,53] represent a species that is distinct from I. potaninii, that this Chinese species belongs to I. sect.Pseudoregelia rather than to I. sect.Psammiris as true I. potaninii, and that I. ser.Tigridiae (with I. tigridia) is a unispecific group belonging to I. sect.Psammiris.A thesis reporting on a genetic study of I. potaninii from China [68] deserves a special mention here.An analysis of 128 individuals from 15 populations has shown that the plants from the Hulunbuir Plateau (northeastern Inner Mongolia, China), where true I. potaninii occur according to the reference [9], exhibit clear genetic differentiation from the plants collected in the Tibetan Plateau, where I. thoroldii is distributed according to Grubov [14] and to the present study.Furthermore, it has provided evidence that the Yushu area is the center of distribution of Tibetan plants' genetic diversity.

Taxonomic Treatment
The results of this study, based on morphological data, show that the Tibetan plants traditionally identified as I. potaninii and currently identified as I. zhaoana should be considered a distinct species because of the well-defined morphological traits discriminating them from I. potaninii.It is undoubtedly I. thoroldii whose original material (Figure 1) is identical to I. potaninii var.ionantha (≡I.zhaoana; Figure 3), except in terms of flower color.Thus, to follow the nomenclatural principles [54], the earliest legitimate name of the taxon, I. thoroldii, is restored here (Art.11.4 of the ICN).
Furthermore, while describing I. thoroldii, Baker cited a single gathering collected by Thorold at the "top of the pass, at 17,800 ft." [10].Grubov [14] (p.100) cited the specimen from K, which was collected from Changtang, a high-altitude plateau in western and northern Tibet, including the southeastern regions of Ladakh, as follows: "Top of the pass, at 17,800 ft.[5430 m], 116 bis, 1891-Thorold, typus!".At K, I found a specimen (K001382250) that belongs to the original material of I. thoroldii.It consists of two plants without flowering stems (Figure 1).However, the protologue of I. thoroldii includes the description of a flowering stem and a flower.This may suggest that specimen K001382250 is a part of the original material, and Baker used uncited specimens when composing the description of I. thoroldii.According to Art. 9.4 of the ICN, original material comprises elements such as specimens and unpublished illustrations that were available to the author prior to, or at the time of, preparation of the description and diagnosis.In the same study on I. thoroldii, Hemsley [10] (p.139) cited the specimen in flowering collected by Woodville Rockhill as follows: "Sharaknyi-gol, hill-slope at 13,800 ft.Lat.N. 35 • 50 ′ , long.E. 93 • 27 ′ ".He indicated the unpublished illustrations as follows: "Hook.Ic.Plant.ined."(i.e., [12]).Also, he noted that I. thoroldii had been described from the specimens collected by Thorold, whereas Rockhill's specimens contain flowers [10].Thorold's gathering (K001382250) and Rockhill's gathering (K001382249) were actually mounted on a single herbarium sheet (Figure 1).Thus, in citing "typus", Grubov designated the specimen in K (K001382250) as the lectotype of I. thoroldii, satisfying the requirements of ICN (see Art. 9.1, Note 1).
The present study has confirmed that two main colors, yellow and blue, are observed in I. thoroldii.However, these are not important for the segregation of I. thoroldii into subspecies or varieties, as the differences have no relationship with distribution.According to Brummitt [56], a form should be a variant of conspicuous morphological feature occurring together with other variants of this feature in mixed populations.Thus, two forms of I. thoroldii are accepted here: the autonymic yellow-flowered form (Figure 2a,c), as indicated in the protologue ("… floribus minoribus sulphureis …") [10], and the form with a blue or purple color (Figure 2b,d), which was described by Zhao as I. potaninii var.ionantha [20].A name at a new rank is proposed here for the form of I. thoroldii with blue or purple color (see Art. 32A.1 of the ICN).
The information on both forms, with full nomenclature citations and main findings on the distribution and habitat of I. thoroldii, is provided below.The accepted names are highlighted in bold.
To the best of my knowledge, it is the Iris species found at the highest elevation.Iris thoroldii is found at elevations ranging from 3200 to 5400 m, or even up to 5800 m [41] (p.537), above sea level and is adapted to a variety of environmental stresses such as extreme temperatures, drought, high winds, high UV radiation, and paucity of soil nutrients.There is every reason to consider it one of the extremely cold-hardy species in I. subgen.Iris (i.e., bearded irises) and, along with another such species I. setosa Pall.ex Link [72], in the genus.
To survive harsh high-elevation environments, I. thoroldii has evolved a number of morphological adaptations to achieve cold hardiness such as the dwarf habit, the vertical rhizome, the contractile adventitious roots, the narrow rosette leaves covered with a waxy coating that is aggregated into a dense tuft and protected from the outside by a few papery leaves, the significantly shortened flowering stem, the pedicel that does not emerge above ground, and the elongated perianth tube supported by surrounding, tightly arranged, and elongated bracts.The fruits are located close to the ground and, therefore, seeds are within the plant, which means that the main mode of seed dispersal is gravity (barochory; see https://ppbc.iplant.cn/tu/28427,accessed on 23 October 2023).Also, the aril attracts ants that are widespread on the Tibetan Plateau [73] and can be involved in the seed dispersal (myrmecochory).Furthermore, I. thoroldii shows remarkable flower color diversity, which contributes to its attractiveness for pollinators.In addition, it is likely that I. thoroldii has adapted to high-elevation habitats through establishing stable symbiosis with arbuscular mycorrhizal fungi [44].
The species is found in sandy, stony, gravelly, pebbly habitats, or on soft black soil in the Tibetan alpine meadows, alpine steppes, and desert steppes, in shady hillsides, on turfed or open slopes and hilltops, among rocks, on wind-eroded ridges, and also on sunny flood plains, gently sloping terraces and plateaus, in ravines, overgrazed areas, and sometimes in spruce forests and scrubs.The flowering time is May to July; the fruiting time is July to August.

Conclusions
The great number of species, abundance of synonyms, and taxonomic complexities have posed some difficulties in understanding the genus Iris, and, therefore, critical studies are needed to address them.The present taxonomic investigation will contribute to our knowledge of the Chinese species, in particular the identity of I. thoroldii, an endemic species to China distributed on the Tibetan Plateau and in adjacent areas, including central Gansu, Qinghai, and northwestern Sichuan provinces, and also Tibet and Xinjiang Uygur autonomous regions.Iris thoroldii has long been recognized as a taxonomic synonym of I. potaninii, with the latter, however, occurring in Russia (southern Siberia), Mongolia, and China (northeastern and western Inner Mongolia, northwestern Heilongjiang Province, and the northern Ningxia Autonomous Region).There is, accordingly, variation in the flower color of I. thoroldii, which has caused much confusion as to the taxonomic circumscription.Thus, depending on the flower color, the Tibetan plants are referred to as two species that are found growing together: those with yellow flowers are erroneously considered I. potaninii, and blue-flowered plants are considered I. zhaoana, a nomenclatural synonym of I. potaninii var.ionantha.
However, a detailed analysis of the protologue information, the existing literature on Iris, herbarium specimens (including original material), and images of living plants clearly indicate that the Tibetan plants are significantly different from I. potaninii in macromorphological characteristics and geographical distribution, and that I. thoroldii should be considered a distinct species.Iris thoroldii can be distinguished from I. potaninii on the basis of the shape of the rhizome, rosette and stem leaves, falls, standards, and aril, and also the length of the flowering stem, bracts, pedicel, and perianth tube.Furthermore, dry plants of I. thoroldii are always easily distinguishable from I. potaninii by the curled remnants of leaves.
The present study is a complete contribution to the taxonomy of I. thoroldii.To avoid further confusion, two forms of I. thoroldii are accepted here: the autonymic yellow-flowered form and the form with blue or purple color, I. thoroldii f. ionantha.I hope that the results obtained will not only be useful for understanding the nomenclature and taxonomy of I. thoroldii, but that they will also stimulate Chinese botanists to undertake more field efforts and study the Iris species in China.In particular, additional information on the chromosome number of I. thoroldii is needed.
It should also be emphasized that, inhabiting elevations up to 5800 m [41], I. thoroldii is the highest-elevation species in the genus Iris and possibly in Iridaceae.In this regard, it may be of interest as a potential source of physiologically active substances.As is known, many active derivatives from high-elevation plants show therapeutic potential [74].Furthermore, I. thoroldii has evolved multiple ecological and reproductive strategies for adapting to the harsh environments of the Tibetan Plateau.For these reasons, it may be considered the perfect material for investigating the physiological capacity of plants at the upper limit of their distribution and the evolution of floral colors.

Supplementary Materials:
The following supporting information can be downloaded at: https:// www.mdpi.com/article/10.3390/plants12223879/s1,Annex 1: Herbarium specimens of Iris thoroldii examined; Table S1: Raw data of the morphological analysis of the Iris species studied (the numbers of the morphological characters correspond to those in Table 1; all measurements are in centimeters).
Funding: This research received no external funding.
Data Availability Statement: All data supporting the reported results are presented as Supplementary Materials.

Table 1 .
Comparative morphology of the Iris species studied.
All measurements are in centimeters.Data are presented as mean (minimum-maximum).See Supplementary raw data in TableS1for more details; for illustrations, see Figures2 and 4.