Phytotaxa 230 (1): 039–053
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Copyright © 2015 Magnolia Press
ISSN 1179-3155 (print edition)
Article
PHYTOTAXA
ISSN 1179-3163 (online edition)
http://dx.doi.org/10.11646/phytotaxa.230.1.3
Afrohybanthus (Violaceae), a new genus for a distinctive and widely distributed
Old World hybanthoid lineage
BENJAMIN J. FLICKER1 & HARVEY E. BALLARD, JR.1,2
1
2
Department of Environmental and Plant Biology, Ohio University, Athens, Ohio 45701, USA
Author for correspondence; email: ballardh@ohio.edu
Abstract
Recent traditional and molecular systematic studies of the violet family, Violaceae, have confirmed extensive polyphyly of
the genus Hybanthus and substantial polyphyly in Rinorea as well. Phylogenetic analyses have proposed up to nine distinct
hybanthoid clades. Broad studies of representative taxa within each clade have revealed coherent suites of macromorphological traits in foliage, flowers, fruits and seeds that easily discriminate the nine hybanthoid lineages from each other and
from currently recognized genera in the family. Base chromosome numbers and biogeography also provide additional support for recognition of the hybanthoid clades as distinct segregate genera. Some hybanthoid clades have available older
generic names, but one of the two Old World lineages, namely the Hybanthus enneaspermus group, is presently nameless.
This clade, distinctive in its ellipsoid, pale yellow, often foveolate seeds, is the most diverse in the Paleotropics, with approximately 25 species distributed across Africa, Madagascar, southern Asia, northern Australia and the southwestern Pacific.
The group is segregated here as Afrohybanthus gen. nov., with new combinations provided for existing names, all of which
have thus far proven morphologically distinct and worthy of recognition at the rank of species. Imminent future studies will
describe additional taxa in the new genus.
Key words: Generic circumscription, Hybanthus, Old World
Introduction
The Violaceae is a medium-sized family with 23 accepted genera and ca. 1,100 species of trees, shrubs, lianas, and herbs
(Ballard, 2007; Ballard et al., 2014; Paula-Souza & Ballard, 2014). The family consists primarily of woody genera
of trees, shrubs and lianas in the New and Old World tropics—Viola being the only sizeable herbaceous temperate
to montane genus. Genera possess great diversity in growth form, inflorescence architecture, floral morphology, and
fruit type. The genus Hybanthus Jacq. is the third largest in the family with ca. 125 species (Ballard et al., 2014),
and is primarily native to the tropics and subtropics; only one species, Hybanthus concolor (T.F. Forst.) Spreng.,
is distributed in temperate eastern North America. Species in the genus range in habit from herbs or subshrubs to
shrubs or (rarely) treelets, and have been traditionally characterized and distinguished from other Violaceae by their
distinctly zygomorphic corolla with the bottom (anterior) petal noticeably or substantially longer than the lateral
and upper ones, differently shaped and often strongly differentiated into an abruptly expanded blade and claw, and
with a “saccate” base; usually free stamens, uncommonly with the filaments fused into a short ring, the bottom pair
of stamens each bearing a gland; fruits a three-valved thin-walled capsule typical of most genera in the family; and
globose to ellipsoidal unwinged seeds. Species inhabit a broad elevational range, from sea-level to 3000 m, and occupy
various habitats from lowland rainforest, savanna and grassland, through temperate and cloud forests, to paramo, with
the greatest diversity of species in forest openings, shrubland and grassland habitats in Latin America, Africa and
Australia. Recent interest has spawned intensive investigations into a bioactive class of proteins, cyclic peptides, and
comparative studies have shown the Violaceae to be particularly rich in these (Broussalis et al., 2001; Ireland et al.,
2006). Studies of cyclic peptide diversity in species of Australian Hybanthus have revealed hundreds of forms and
shown that peptide composition closely reflected apparent morphological relationships among taxa (Simonsen et al.,
2005).
Accepted by Zhi-Qiang Zhang: 1 Jun. 2015; published: 6 Oct. 2015
Licensed under a Creative Commons Attribution License http://creativecommons.org/licenses/by/3.0
39
Taxonomic history of Hybanthus
Nicolaus Jacquin first described Hybanthus in 1760 based on the type species Hybanthus havanensis Jacq. Several other
genera were described as allies to Hybanthus by various authors over the next 160 years, including Pombalia Vand.
(1771), Solea Spreng. (1800), Ionidium Vent. (1803), Ionia Pers. ex Steud. (1821), Pigea DC. (1824), Ionia Steud.
(1840), Vlamingia De Vries (1845), Acentra Phil. (1870), Cubelium Raf. ex Britton & A.Br. (1897) and Clelandia J.M.
Black (1932). Most of these names were based on various Neotropical hybanthoid taxa as type species. The exceptions
are Clelandia, Pigea and Vlamingia, which have been erected for species of southern Australia, with Pigea the earliest
available and validly published generic name, relating to taxa in the Hybanthus caledonicus group (Wahlert et al.,
2014). No generic names have ever been applied to Old World hybanthoid taxa outside of Australia, and particularly
those of the Hybanthus enneaspermus group widespread through Africa and Madagascar, tropical Asia, and northern
Australia.
During the last half-century there has been an increasing trend toward synonymy of segregate genera due to the lack
of apparently consistent distinctions, favoring a broad concept of Hybanthus. Although Airy Shaw in 1966 recognized
Clelandia as a distinct genus, and Hutchinson (1967) recognized Cubelium, all others have since followed Melchior
(1925) in recognizing a single broadly defined genus, Hybanthus. This trend toward few, broadly delimited taxa at
the generic level was also fostered extensively at the species level, especially in Africa and tropical Asia, resulting in
comparatively few species (and in the case of Hybanthus enneaspermus, many infraspecific taxa; e.g., Grey-Wilson
1981). To date no comprehensive monograph has been published for the genus as presently circumscribed, although a
few regional treatments have been completed. Bennett (1972) revised the Australian taxa of Hybanthus and described
the section Variabiles for the southern Australian taxa based on differences in base chromosome number, calcium
oxalate crystal shape and distribution, staminal gland morphology, and seed and embryo morphology. The remaining
Australian taxa were left in sect. Suffruticosi.
Evidence from DNA, morphology, chromosome numbers and geography
Recent molecular phylogenetic results (Fig. 1) for the Violaceae have demonstrated that Hybanthus is polyphyletic,
with species in nine morphologically and biogeographically distinct clades (Feng, 2005; Wahlert et al., 2014). Results
further show that the Hybanthus enneaspermus group to occupy a basal position in a broader clade with several
other New World and Old World genera and hybanthoid groups, but well removed from the Old World Hybanthus
caledonicus group and Hybanthus sensu stricto.
All hybanthoid clades can be easily distinguished by suites of morphological and anatomical characters including
habit, degree of woodiness, branch and stipule morphology, inflorescence type, extent of zygomorphy (relative
elongation of bottom petal to lateral and upper ones); basal expansion and differentiation of bottom petal; filament
connation; staminal gland shape and position; seed number per valve and capsule, seed shape, size, color and surface
sculpturing.
The overall phylogenetic distribution of inferred base chromosome numbers across the family also differentiates
the Hybanthus clades into two assemblages, with basal genera possessing numbers based on x = 6 and derived ones
(which form a monophyletic group including other genera) based on x = 8.
Geographic distributions of the nine clades are mostly non-overlapping, except for certain areas of Latin America.
Seven clades are restricted to the New World, while two are confined to the Old World. The genus Hybanthus in the
narrow sense is currently being re-circumscribed by the second author to represent a group of three Mesoamerican and
Antillean species with woody shrub or treelet habit, long-pedunculate dichasial inflorescences, weakly zygomorphic
corollas with a bottom petal greatly distended at base, filaments fully connate into a tube, a single lunate shield-like
gland spanning the two bottom stamens, asymmetrical capsule with 1–2 seeds, and seeds large, subglobose, dark
brown and minutely roughened.
The Hybanthus enneaspermus group represents one of two clades of Hybanthus sensu lato restricted to the
Paleotropics, the other being the Hybanthus caledonicus group (Feng, 2005; Wahlert et al., 2014). The Hybanthus
enneaspermus group is phylogenetically distinct, and preliminary studies indicate that it possesses numerous
macromorphological distinctions across foliage, flowers, capsules and seeds that set it apart from Hybanthus sensu
stricto and all other hybanthoid groups revealed by recent phylogenetic investigations. Plants are typically herbs with
some semi-woody subshrubs and shrubs. The clade is distributed broadly throughout most of the Old World Tropics,
and has a center of taxonomic diversity in Tropical East Africa. Geographically, the clade overlaps only slightly with
the Hybanthus caledonicus group in parts of central Australia. The objective of this study was to clarify the distinctions
of the Hybanthus enneaspermus group from other hybanthoid groups, in particular Hybanthus sensu stricto and the
Hybanthus caledonicus group, and to provide nomenclatural combinations for existing names under a new segregate
genus.
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FLICKER & BALLARD
FIGURE 1. Chloroplast phylogeny of the Violaceae; arrows point to Old World groups and Hybanthus sensu stricto (redrawn from
Wahlert et al., 2014). Numbers above branches are maximum likelihood bootstrap/Bayesian posterior probabilities; solid circles indicate
100%/1.00 support for a branch.
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Phytotaxa 230 (1) © 2015 Magnolia Press • 41
Materials and methods
Morphology and distribution were determined from more than 900 herbarium specimens from A, B, BM, BR, BSM,
C, CBG, CHAPA, DuKE, F, G, GH, HBG, IBuG, IEB, INB, K, L, LL, M, MEXu, MICH, MO, NY, P, POM, RSA,
S, TEX, u, uS, W, WAG, WIS, XAL and Z (herbarium acronyms follow Thiers 2014). Taxa in the three most relevant
Hybanthus groups were compared in this study: Hybanthus sensu stricto, the Hybanthus enneaspermus group, and the
Hybanthus caledonicus group. Flowers were dissected after briefly soaking in a weak soap water solution. Images of
floral parts, capsules, seeds and other small structures were captured with an Olympus SZ61 dissecting microscope
and an Olympus SC30 videocapture imaging system. Measurements of floral, capsule and seed traits were made using
ImageJ software (Abromoff et al., 2004).
Results
The Hybanthus enneaspermus group is immediately distinguishable morphologically from other hybanthoid groups
by many characters. Characters particularly separating it from Hybanthus sensu stricto and the Hybanthus caledonicus
group (Table 1) include differences in inflorescence type; degree of corolla zygomorphy; relative differentiation of the
bottom petal; relative expansion or extension of the base of the bottom petal; extent of filament connation; number,
shape and attachment of the staminal glands (Fig. 2, a–c); number of seeds per valve or capsule; and shape, color and
surface ornamentation of the seed (Fig. 2, d–f).
TABLE 1. Overview of traits distinguishing Afrohybanthus from the type material of Hybanthus sensu stricto and the other Old World
clade, the South Australian/ South Pacific Hybanthus caledonicus clade.
Group
Inflorescence
Type
Base of bottom
petal
Filament
connation
Gland #
Seed surface
Seed color
Afrohybanthus
Solitary
Spurred
Short collar
2
Ribbed or foveolate
(smooth)
Pale yellow
Hybanthus sensu
stricto
Dichasium
Distended
Fully connate
1
Minutely roughened
Dark brown with
pale markings
Hybanthus
caledonicus group
Solitary
(racemes,
monochasium)
Spurred
(saccate)
Short Collar
2
Pusticulate
Dark brown
TABLE 1. (Continued)
Group
Corolla zygomorphy
(lateral: bottom petal)
Gland position on bottom
stamen
Seeds per capsule
Distribution
Afrohybanthus
.38–.66
Medial to upper medial
(6) 9, 12, 15 (18)
Paleotropics
Hybanthus sensu stricto
.75–.89
Summit of filament tube
1–2
Antilles, Mesoamerica
Hybanthus caledonicus
group
.30–.66
Basal
1–3 (6)
South Australia/ South
Pacific
Chromosome numbers in the two Old World groups appear to parallel the two base numbers apparent in the
family overall. Numbers appear to be based on x = 8 in the H. enneaspermus group (Hybanthus aurantiacus F. Muell.
ex Benth., n = 8, Bennett, 1972; H. enneaspermus (L.) F. Muell., n = 8, Bennett, 1972, Peng and Chen, 1985; H.
enneaspermus, n = 16, Mangenot and Mangenot, 1962, Sarkar et al., 1980), as opposed to x = 6 for species of the
Hybanthus caledonicus group in southern Australia and New Caledonia (see Bennett, 1972).
The numerous morphological distinctions of the Hybanthus enneaspermus group, its somewhat isolated cladistic
position especially with regard to Hybanthus sensu stricto and the Hybanthus caledonicus group, its allopatric Old
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FLICKER & BALLARD
World distribution, and different base chromosome number from the Hybanthus caledonicus group (and presumably
Hybanthus sensu stricto), provide compelling evidence for recognition of the Hybanthus enneaspermus group as a
separate genus. No available generic name exists that applies specifically to taxa in the group under scrutiny. Therefore,
the Hybanthus enneaspermus group is described under a new name, Afrohybanthus.
FIGURE 2. Staminal gland and seed morphologies of three different hybanthoid clades. a & d. Hybanthus sensu stricto (H. havavensis)
(a. Contreras 8540 [MO], d. Lundell & Lundell 8540 [MO]). b & e. Afrohybanthus (A. enneaspermus) (b. Wood 2171 [K], e. faden &
faden 74/1216 [K]). c & f. Hybanthus caledonicus group (H. caledonicus) (c. Melville & Coleman 4481 [K], f. Salasoo 4441 [K]). Arrows
indicate the staminal glands, scale bars are all 1 mm.
Afrohybanthus Flicker gen. nov.
Diagnosis. The new genus is similar to southern Australian taxa in the Old World Hybanthus caledonicus group and
many New World taxa, but divergent from Hybanthus sensu stricto in having solitary flowers, strongly zygomorphic
corollas with a well differentiated bottom petal, filaments basally connate into a short “collar” with free portions to the
filaments, two staminal glands, and 3–5 seeds per capsule valve. It shares with the Hybanthus caledonicus group a short
but distinct spur at the base of the bottom petal, rather than a merely saccate or distended bottom petal characteristic
of most New World taxa including Hybanthus sensu stricto. It is different from the Hybanthus caledonicus group in
the elongate glands with medial or upper attachment on the filaments, and is unique in producing ellipsoid to narrowly
ovoid, pale yellow or honey-colored seeds commonly with longitudinal ribs and/or foveolae in several to many lines.
Description. Herbs, subshrubs, occasionally shrubs 10 cm to 3 m. tall, stems glabrous to scarcely pubescent, occasionally
densely pubescent. Leaves simple, alternate, occasionally fascicled, sessile to subsessile, linear to obovate, 0.5–8 cm
long, 0.1–1.8 cm wide, base cuneate, lamina herbaceous to chartaceous, veins reticulate, margins entire to denticulate,
occasionally with violoid gland on teeth and at apex, glabrous or pubescent, stipules persistent to deciduous, linear to
lanceolate, apex acute, occasionally glandular tipped, 1.5–6 mm long, membranous to herbaceous, glabrous to sparsely
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pubescent, ciliate along the margins. Inflorescences of axillary solitary flowers, peduncles 2–8 mm long, glabrous to
pubescent, peduncle bracts subopposite, positioned in the apical half to third near articulation point, membranous,
lanceolate, usually glandular tipped, glabrous to pubescent, up to 3 mm long, summit ending at articulation between
peduncle and pedicel. flowers borne on a pedicel (from articulation to base of flower) 5–30 mm long, glabrous to
pubescent, 6–25 mm long, sepals 5, herbaceous, subequal, 2.5–4 mm long, pubescent along costa, occasionally ciliate
along the entire margins, 3–7-nerved, upper 3 lanceolate, bottom 2 falcate-lanceolate, all with apex acute. Corolla
strongly zygomorphic, petals white, yellow, pink or purple, herbaceous, glabrous, upper pair lance-ovate, 3–6 mm
long, rarely exceeding the calyx, 3–5 nerved, lateral pair falcate, 4–7 mm long, slightly exceeding the calyx, 7–9nerved, basal petal spurred , strongly clawed, with large blade exceeding the calyx, spatulate to orbicular, apex obtuse
occasionally cuspidate or retuse, 8–20 mm long, 2–6 mm wide, often marked with a honey guide. Filaments 1.5–2.5
mm long, connate at base into a minute “collar” less than 1 mm long, free portion above filament tube about 1 mm
long, the bottom pair of stamens each with a nectary gland attached medially or in the upper third of the free portion of
the filament, glands petioled up to 1 mm long, occasionally sessile, glands usually with a tuft of hairs. Anthers 1.5–4
mm, glabrous, the bottom 2 occasionally with long hairs along the costa of the anther connective, dorsal connective
scales short, ovate, glabrous, margin entire, apex rounded. Ovary globose, 1.1–2 mm long, 0.7–1.1 mm wide, glabrous,
rarely densely short-pubescent. Style slightly exceeding the anthers, up to 4 mm long, thickened at the tip. fruit a
three-valved capsule, glabrous, rarely short-pubescent, straw-colored at maturity, occasionally pale green, 4–9 mm
long. Seeds typically 9, 12 or 15 (3–5 per valve), rarely 6 or 18, pale yellow or honey-colored, typically ribbed and/or
foveolate longitudinally in several to many lines, very rarely smooth, narrowly ovoid to ellipsoid, glabrous, 1.2–2.1
mm long, 0.6–1.8 mm wide. Chromosome numbers based on x = 8.
Type species: Viola enneasperma L.
Etymology:—The name is based on a combination of the regional center of taxonomic diversity for the H.
enneaspermus group (Africa) and the broadly defined genus to which this and other hybanthoid lineages have previously
been allied.
New Combinations
The following combinations are arranged alphabetically. New combinations are made at the species level. Herbarium
investigations support recognition of most previously described taxa, and studies have confirmed that they diverge
consistently in multiple features of habit, flowers, capsules and/or seeds. The substantial morphological differentiation,
and also commonly non-overlapping geographic distributions and separate habitats, urges recognition of all taxa at
the rank of species. In most cases of lectotypes designated in this manuscript, an image of the selected lectotype is
presented as a figure.
Afrohybanthus aurantiacus (F. Muell. ex Benth.) Flicker, comb. nov. ≡ Ionidium aurantiacum F. Muell. ex Benth., fl.
Austr. 1: 102. 1863 ≡ Hybanthus aurantiacus (F.Muell. ex Benth.) F.Muell., Pl. North West Austr.: 5. 1881 ≡ Hybanthus
enneaspermus var. aurantiacus (F.Muell. ex Benth.) F.Muell., Pl. Indig. Shark Bay: 6. 1883. Type:—NW Coast of
Australia, Byrnes s.n. (lectotype K000327678!, designated here); Fig. 3.
Note: A lectotype was chosen from the two specimens cited by Bentham, who failed to designate a holotype.
Afrohybanthus buxifolius (Vent.) Flicker, comb. nov. ≡ Ionidium buxifolium Vent., Jard. Malmaison: sub pl. 27. 1803
≡ Viola buxifolia (Vent.) Juss. ex Poir., Encycl. 8: 646. 1808 ≡ Hybanthus buxifolius (Vent.) Baill., Bull., Soc. Linn. 1:
584. 1886. Type:—Madagascar, Commerson s.n. (holotype P-Ju!).
Afrohybanthus caffer (Sond.) Flicker, comb. nov. ≡ Ionidium caffrum Sond., Linnaea 23: 13. 1850 ≡ Hybanthus caffer
(Sond.) Engl., Bot. Jahrb. 55: 400. 1919 ≡ Hybanthus enneaspermus (L.) F.Muell. var. caffer (Sond.) Robson, Bol. Soc.
Brot. Ser. 2A 32: 169. 1958. Type:—Port Natal, South Africa, Gueinzius 94 (holotype S!).
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FIGURE 3. Lectotype designated here of Ionidium aurantiacum F. Muell. ex Benth.
Afrohybanthus danguyanus (H. Perrier) Flicker, comb. nov. ≡ Hybanthus danguyanus H. Perrier, Memoires de l’Institut
Scientifique de Madagascar, Serie B. Biologie Vegetale 2: 312–313. 1949. Type:—Boina, Western Madagascar, middle
basin upstream of Bemarivo, Perrier 5070 (lectotype P030552!, designated here); Fig. 4.
Note: A lectotype was selected from the three specimens cited by Perrier, as none of them were explicitly identified by
the author as the holotype.
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FIGURE 4. Lectotype designated here of Hybanthus danguyanus H. Perrier.
Afrohybanthus decaryanus (H. Perrier) Flicker, comb. nov. ≡ Hybanthus decaryanus H. Perrier, Memoires de l’Institut
Scientifique de Madagascar, Serie B, Biologie Vegetale 2:312–313. 1949. Type:—Ikonka South of Ambovombe,
Madagascar, M. Decary 9396 (holotype P!).
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Afrohybanthus densifolius (Engl.) Flicker, comb. nov. ≡ Hybanthus densifolius Engl., Bot. Jahrb. 55: 398. 1919.
Type:—Namibia, Dinter 430 (lectotype P00631583!, designated here); Fig. 5.
Note: A lectotype was designated because the holotype at B was destroyed.
FIGURE 5. Lectotype designated here of Hybanthus densifolius Engl.
Afrohybanthus enneaspermus (L.) Flicker, comb. nov. ≡ Viola enneasperma L., Sp. Pl. 2: 937. 1753 ≡ Ionidium
enneaspermum (L.) Vent., Jard. Malmaison 1 (5): sub. pl. 27. 1803 ≡ Hybanthus enneaspermus (L.) F.Muell., fragm.
Phyt. Austr. 10: 81. 1876.
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Type:—Sri Lanka, Hermann s.n. in Vol. I, p. 19 of Hb. Hermann (lectotype BM!, designated by Grey-Wilson, 1986).
= Viola suffruticosa L., Sp. Pl. 2: 937. 1753 ≡ Ionidium suffruticosum (L.) Roem. & Schult., Syst. Veg. 5: 394. 1819 ≡
Hybanthus suffruticosus (L.) Baill., Traite bot. med. Phan. 2(3): 841. 1884. Type:—Sri Lanka, Hermann s.n. in Vol. I,
p. 41 of Hb. Hermann (lectotype BM!, designated by Grey-Wilson, 1986).
= Ionidium heterophyllum Vent., Jard. Malmaison 1(5): sub pl. 27. 1803 ≡ Hybanthus heterophyllus (Vent.) Baill.,
Traite bot. med. Phan. 2(3): 841. 1884. Type:—China Herb., d’Incarville 109 (holotype P-Ju!).
= Viola linifolia Poir., Encyc. Meth. Bot. 8: 647. 1808 ≡ Ionidium linifolium (Poir) Roem. & Schultes, Syst. Veg.
5: 392. 1819 ≡ Hybanthus linifolius (Poir) Baill., Bull. Mens. Soc. Linn. Paris 1: 554. 1886. Type:—Madagascar,
Commerson s.n. (holotype P-Ju!).
= Viola thesiifolia Juss. ex Poir., Encycl. 8: 649. 1808. ≡ Ionidium thesiifolium (Juss. ex Poir.) Roem. & Schultes,
Syst. Veg. 5: 398. 1819 ≡ Hybanthus thesiifolius (Juss. ex Poir.) Hutch. & Dalziel, fl. W. Trop. Afr. 1: 97. 1927. Type:—
Senegal, Adanson 111A (holotype P-Ju!).
= Ionidium hexaspermum Dalz., Hooker’s J. Bot. Kew Gard. Misc. 4: 342. 1852. Type:—West India, near Belgaum,
Dalzell s.n. (holotype K!).
= Ionidium aethiopicum Turcz., Bull. Soc. Nat. Mosc. 27(2): 339. 1854. Type:—Sudan, Mt. Arasch-Cool, Kotschy
42 (holotype KW001000995, isotype K000231118!).
= Ionidium hirtum Klotsch, Reise Mossamb. Bot.: 148. 1861 ≡ Ionidium enneaspermum var. hirtum (Klotzsch)
Oliv., fl. trop. Afr. I: 106. 1868 ≡ Hybanthus hirtus (Klotsch) Engl., Bot. Jahrb. 55: 398. 1919. Type:—Kenya, Northern
Frontier District, near Malka Korokoru in sandy steppe, f. Thomas 88 (lectotype K!, designated here).
Note: A lectotype was designated because the holotype at B was destroyed.
= Ionidium indicum Capitaine Bull. Soc. Bot. france 57: 396. 1910.
= Hybanthus enneaspermus var. diversifolius Grey-Wilson, Kew Bull. 36: 106. 1981. Type: —Kenya, Arabuko,
R.M. Grahams 1983 (holotype K, seen as image!, isotype K000231110, seen as image!).
Afrohybanthus fasciculatus (Grey-Wilson) Flicker, comb. nov. ≡ Hybanthus fasciculatus Grey-Wilson, Kew Bull. 36
(1): 110. 1981. Type:—Meru National Park, Kenya, P.H. Hamilton 163 (holotype K!).
Afrohybanthus latifolius (De Wild.) Flicker, comb. nov. ≡ Ionidium enneaspermum (L.) Vent. var. latifolium De Wild.,
Pl. Thonn. Cong., ser. 2: 238, fig. 17. 1911 ≡ Hybanthus enneaspermus (L.) F.Muell. var. latifolius (De Wild.) Engl.,
Bot. Jahrb. Syst. 55: 398. 1919 ≡ Hybanthus latifolius (De Wild.) A. Chev., fl. Afrique occ. franc. 1. 228. 1938.
Type:—ubangi, Democratic Republic of Congo, fr. Thonner 203 (holotype BR!).
Afrohybanthus nyassensis (Engl.) Flicker, comb. nov. ≡ Ionidium nyassense Engl., Pflanzenw. Ost-Afr. C: 277. 1895
≡ Hybanthus nyassensis (Engl.) Engl., Bot. Jahrb. Syst. 55: 400. 1919 ≡ Hybanthus enneaspermus (L.) F.Muell. var.
nyassensis N. Robson, Bol. Soc. Brot. Ser. 2A 32: 168. 1958. Type:—Shire Highlands, Blantyre, Malawi, Last s.n.
(lectotype K!, designated by Grey-Wilson, 1986).
Note: This taxon has been raised to specific rank due to its combination of plentiful branching at the base, oblanceolate
leaves, and bottom petal shape that is unique in the new genus.
Afrohybanthus pseudodanguyanus (Grey-Wilson) Flicker, comb. nov. ≡ Hybanthus enneaspermus (L.) F. Muell. var.
pseudodanguyanus Grey-Wilson, Kew Bull. 39 (4): 771. 1984. Type:—Meru National Park, Kenya, P.H. Hamilton 203
(holotype K!).
Note: This taxon has been raised to specific rank due to its combination of leaves with dentate margins; short, pubescent
staminal glands; and seeds with lateral striations (foveolae longitudinally arranged in lines).
Afrohybanthus ramosissimus (Thwaites) Flicker, comb. nov. ≡ Ionidium ramosissimum Thwaites, Enum. Pl. Zeyl.:
21. 1864 ≡ Hybanthus ramosissimus (Thwaites) Melch. in Engl. & Prantl, Nat. Pflanzenfam., ed. 2 21: 360. 1925.
Type:—Maharagama, Sri Lanka, Thwaites 1084 (lectotype K000327681!, designated here, photo at uS!); Fig. 6.
Note: Although a single collection was specified in the protologue, it is uncertain whether herbarium specimens at
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FLICKER & BALLARD
K, PDA or both were used by Thwaites in describing the species (Stafleu & Cowan, 1986). Therefore, the K sheet is
selected as the lectotype.
FIGURE 6. Lectotype designated here of Ionidium ramosissimum Thwaites.
Afrohybanthus serratus (Engl.) Flicker, comb. nov. ≡ Hybanthus enneaspermus (L.) F. Muell. var. serratus Engl., Bot.
Jahrb. Syst. 55: 398. 1919. Type: South Africa Schlechter 4218 (lectotype K000231107!, designated here); Fig. 7.
Note: A lectotype was designated because the holotype at B was destroyed. This taxon has been raised to specific rank
due to its serrate/dentate leaf margins and green capsules, the walls of which are thickened along the costa of each
valve, appearing trilobate in cross section. This represents a unique combination of characters in the new genus.
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FIGURE 7. Lectotype designated here of Hybanthus enneaspermus var. serratus Engl.
Afrohybanthus stellarioides (P.Forster) Flicker, comb. nov. ≡ Hybanthus enneaspermus var. stellarioides Domin,
Biblioth. Bot. 89: 983. 1928 ≡ Hybanthus enneaspermus subsp. stellarioides (Domin) E. Bennett, Nuytsia 1: 229. 1972
≡ Hybanthus stellarioides (Domin) P.Forster, Muellaria 8(1): 18. 1993. Type:—Cook District, Queensland, Australia.
K. Domin 6794 (holotype PR, seen as image!).
Afrohybanthus travancoricus (Bedd.) Flicker, comb. nov. ≡ Ionidium travancoricum Bedd., Icones Plantarum Indiae
Orientalis 1: 55. 1874. Type:—Sri Lanka, Beddome 320 (lectotype K000327683!, designated here); Fig. 8.
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Note: Beddome used specimens and deposited types from BM, K and CAL (Stafleu & Cowan, 1976). Because the
status of individual specimens is uncertain, a K sheet has been selected as the lectotype.
FIGURE 8. Lectotype designated here of Ionidium travancoricum Bedd.
Afrohybanthus tsavoensis (Grey-Wilson) Flicker, comb. nov. ≡ Hybanthus enneaspermus (L.) F.Muell. var. tsavoensis
Grey-Wilson, Kew Bull. 36(1): 106. 1981. Type:—Tsavo Park, Kenya, Greenway & Kanuri 12916 (holotype K!).
Note: This taxon has been raised to specific rank due to its distinctive dense woolly pubescence (unique in the new
genus) as well as its floral size, basal petal shape, and corolla color that differentiate it from A. enneaspermus.
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Afrohybanthus verbi-divini (Everaarts) Flicker, comb. nov. ≡ Hybanthus enneaspermus (L.) F.Muell. var. verbi-divini
Everaarts, fl. Malesiana 7: 831. 1971. Type:—Flores, Lower Sunda Islands, Schmutz 3135 (holotype L!).
Note: This taxon has been raised to specific rank due to its unique combination of large, dark red corollas, consistently
larger height (up to 2 meters tall), and relatively large, smooth seeds atypical for the genus.
Uncertain taxa
All Engler names below were originally based on type material in Berlin, now destroyed. No duplicates have been
located to serve as lectotypes, and no collections have been found that unambiguously match the protologues. Similarly,
no type specimens have been verified for Ionidium thymifolium, and the protologue is vague; the taxonomic status of
that name remains unclear. Hybanthus enneaspermus var. pseudocaffer retained here, as further studies are needed
to determine whether it should be synonymized under Hybanthus enneaspermus or be recognized as distinct at some
taxonomic rank.
Hybanthus fritzcheanus Engl., Bot. Jahrb. 55: 398. 1919.
Hybanthus hildebrandtii Engl., Bot. Jahrb. 55: 398. 1919.
Hybanthus hirtus (Klotzsch) Engl. var. glabrescens Engl., Bot. Jahrb. 55: 399. 1919.
Hybanthus hirtus (Klotzsch) Engl. var. klotzschii Engl., Bot. Jahrb. 55: 400. 1919.
Ionidium thymifolium Presl, Bot. Bem. 11. 1845.
Hybanthus enneaspermus var. pseudocaffer Grey-Wilson, Kew Bull. 36: 109. 1981. Type: —Tanganyika, Steinbruch forest area, faulkner
2026 (holotype K000231111, image seen!).
Discussion
Distinctive androecial or seed traits alone are sufficient to confidently assign taxa to this or any other Hybanthus group;
but the suite of distinctions in vegetative, floral and fruit structures cumulatively support recognition of this and other
clades on par with other currently recognized genera of Violaceae. Fewer traits have been used to distinguish other
long-recognized genera in the Violaceae, e.g., Mayanaea and Orthion, Rinoreocarpus and Rinorea, Noisettia and Viola
(see Ballard et al., 2014).
Nearly all hybanthoid taxa in Africa, southern Asia and northern Australia are here assigned to the new genus.
However, Hybanthus capensis (Thunb.) Engl. from the Cape region of Africa possesses features of bottom petal spur,
staminal glands and seeds that are diagnostic of the Hybanthus caledonicus group, and that species is tentatively
excluded from Afrohybanthus. Future manuscripts will examine prospective new taxa under Afrohybanthus.
Acknowledgments
We thank the curators and collections managers at the herbaria mentioned in the Materials and Methods for access to
specimens, and anonymous reviewers and editors for suggestions that improved the manuscript.
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