Three species are included in this revision of the Afrotropical sawfly genus Durbadnus Pasteels, 1954: D. chubbi (Forsius, 1930), D. obscuripes (Forsius, 1931) comb. n. and D. taegeri sp. n. A new junior synonym of D. chubbi is Blennocampa bensoni Forsius, 1931 (syn. n. ). The genus Durbadnus is restricted to South Africa, with D. taegeri being the first recorded member of the Tenthredinidae in the winter-rainfall zone of western South Africa. A key is provided to the five Afrotropical genera of Blennocampinae (Aethiocampa, Distega, Durbadnus, Tesslinia and Trisodontophyes). Kivua Forsius, 1934 is transferred from the Blennocampinae to the Allantinae. New junior synonyms of Kivua are Bicrista Pasteels, 1949 (syn. n.), Tumura Pasteels, 1949 (syn. n.) and Urocerca Pasteels, 1949 (syn. n.). The following new combinations result: Kivua bicolor comb. n. (Bicrista bicolor Pasteels, 1949), Kivua acuticornis comb. n. (Erythraspides acuticornis Pasteels, 1953), Kivua afra comb. n. (Erythraspides afra Pasteels, 1953), Kivua cribrifrons comb. n. (Urocerca cribrifrons Pasteels, 1949), Kivua pallipes comb. n. (Urocerca pallipes Pasteels, 1949) and Kivua tenuis comb. n. (Urocerca tenuis Pasteels, 1949). The specific epithet luteiventris is preoccupied in Kivua by K. luteiventris Pasteels, 1949, so that new names are proposed for two further species group taxa transferred here to Kivua: Kivua violae nom. n. for Tumura luteiventris Pasteels, 1949 and Kivua cara nom. n. for Urocerca luteiventris Pasteels, 1949. Neacidiophora quadrifoveata Koch, 1998 is a junior synonym of Kivua incrassata Pasteels, 1949 (syn. n.).
INTRODUCTION
The arid to semiarid winter-rainfall zone of Namibia and South Africa stretches West of a line from Swakopmund on the Atlantic coast of Namibia to Mossel Bay on the Western Cape coast of South Africa. The northern part of the zone is characterized by the Succulent Karoo Biome and the southern part by the Fynbos Biome with its richer floral diversity. Our very poor knowledge of the Symphyta of the winter-rainfall zone is explained by the restricted diversity of the sawfly fauna, the low abundance of these few taxa, and by the lack of field work so far specifically targeted on this group. Hitherto, 23 species of Argidae (Tenthredinoidea) have been the only indigenous Symphyta known from this area: nine species of Triarge Forsius, 1931 (Koch 2006, 2010) and 14 species of Arge Schrank, 1802 (Pasteels 1953, 1955, 1963; Koch & Goergen 2010). Additionally, three Tenthredinidae (Caliroa cerasi (L., 1758), Fenusa dohrnii (Tischbein, 1846) and Nematus oligospilus Förster, 1854), as well as the siricid Sirex noctilio Fabricius, 1793 are established, introduced species. During recent studies on the sawfly fauna of this area, one previously undescribed and probably endemic species of the family Tenthredinidae (Tenthredinoidea) was discovered. Initially, the new species described below was thought to belong to Distega Konow, 1904. Further research showed that it should be placed in Durbadnus Pasteels, 1954. A revision of Durbadnus became necessary to resolve the identity of the new species, which in turn revealed problems, here briefly outlined, affecting the characterisation of other Afrotropical genera previously that were placed in the Blennocampinae, as well as the distinction of Allantinae from Blennocampinae in the Afrotropical fauna. Here, a first attempt is made to review and key the Afrotropical genera of Blennocampinae.
MATERIAL AND METHODS
The examined material examined is in the following collections (institutional codens used in the text follow Evenhuis (2011)):
BMNH —
The Natural History Museum, London, UK;
SDEI —
Senckenberg Deutsches Entomologisches Institut, Müncheberg, Germany;
DMSA —
Natural Science Museum, Durban, South Africa;
USNM —
National Museum of Natural History, Smithsonian Institution, Washington, DC, USA;
UZMT —
Museum Zoologicum, Åbo Academi, Turku, Finland;
ZMHB —
Museum für Naturkunde der Humboldt-Universität, Berlin, Germany.
The terminology of wing venation follows Goulet (1992). Except for Durbadnus species, original descriptions are not cited in full. Detailed citations are to be found in Taeger et al. (2010).
Morphological abbreviations
Wing cells: fore wing: 2A — second anal, 1R1 — first radial 1, 1Rs — first radial sector, 2Rs — second radial sector; hind wing: 1A — first anal, M — medial, Rs — radial sector. Wing veins: fore wing: 2A+3A — second and third anal vein, M — media, R — radius, Rs+M — radial sector and media, a — anal crossvein, 1m-cu — mediocubital crossvein, 2r-m — second radiomedial crossvein; hind wing: 1A — first anal vein. Male genitalia: H — harpe, Pp — parapenis. The following abbreviations and measurements are used: OOL — ocellarocular line, POL — posterior ocellar line (postocellar line).
TAXONOMY
Distinction between Blennocampinae and Allantinae
The classification of the Blennocampinae and Allantinae has been treated in many different ways, as reviewed by Lacourt (2003). In the European and North American faunas, Allantinae can be clearly identified by possession a fully developed (closed) and barely medially constricted fore wing anal cell, which in Blennocampinae is basally reduced (open, or petiolate), except in Lycaotini (Goulet 1992), where it is complete but strongly constricted. This distinction breaks down in the Afrotropical fauna, where the development of the fore wing anal cell varies considerably within some genera: particularly Kivua (Pasteels 1949b), but very rarely also in Distega, especially D. bevisi Forsius, 1930 (Fig. 2). The phylogeny and classification of the approximately 112 described genera of Allantinae and 106 genera of Blennocampinae in the world that are currently considered to be valid (Taeger et al. 2010), are in great need of intensive study. As already noted by Benson (1938), both subfamilies as presently constituted are probably polyphyletic. For the purposes of the present work, as a purely pragmatic and provisional solution to permit identification, Afrotropical Blennocampinae are distinguished from Allantinae as follows:
— Anal cell of fore wing complete, or if veins 2A+3A are reduced, then combined length of flagellomeres4–7 less than half as long as remainder of flagellum, flagellomere4 usually much shorter than flagellomere3 (maximally 0.6 as long) and ventral surface of all or any of flagellomeres4–7 with a discrete patch (sometimes concave, or paler than rest of flagellomere) bearing setae shorter than those on remaining surface Allantinae
— Anal cell of fore wing (3A) incomplete (petiolate, with veins 2A+3A reduced, as in Fig. 6). Combined length of flagellomeres4–7 more than half as long as remainder of flagellum, flagellomere4 always at least 0.6 as long as flagellomere3 and ventral surface of flagellomeres4–7 not different from rest of surface Blennocampinae
The modified underside of the apical flagellomeres and the general pattern of flagellomere length ratios in Afrotropical Allantinae, but not in any Afrotropical Blennocampinae, are characters that are usually considered to characterize the Waldheimini (e.g. Goulet 1992). The Waldheimini as currently defined are generally, however, regarded as belonging to the Blennocampinae. The phylogenetic significance of these characters is at present unclear.
Taxonomy of Afrotropical Blennocampinae and some Allantinae
Abe and Smith (1991) and Taeger et al. (2010) listed nine valid genera of Blennocampinae as occurring in the Afrotropical Region: Aethiocampa Pasteels, 1949 (type species: Blennocampa aethiopica Enslin, 1913), Bicrista Pasteels, 1949 (type species: Bicrista bicolor Pasteels, 1949), Distega Konow, 1904 (type species: Distega sjoestedti Konow, 1904), Durbadnus Pasteels, 1954 (type species: Monophadnus chubbi Forsius, 1930), Kivua Forsius, 1934 (type species: Kivua seydeli Forsius, 1934), Tesslinia Pasteels, 1951 (type species: Blennocampa afra Enslin, 1913), Trisodontophyes Enslin, 1911 (type species: Trisodontophyes nigroflava Enslin, 1911), Tumura Pasteels, 1949 (type species: Tumura luteiventris Pasteels, 1949) and Urocerca Pasteels, 1949 (type species: Urocerca luteiventris Pasteels, 1949). The type species of all these genera have been examined, and it was concluded that Bicrista (syn. n.), Tumura (syn. n.) and Urocerca (syn. n.) are junior synonyms of Kivua. These taxa had been distinguished from Kivua (s. str.) by single character states. Urocerca was characterized by the form of the cerci, as described by Pasteels (1949a), suggesting that the species concerned may differ in oviposition habits from other Kivua species. Bicrista and Tumura were erected mainly on the basis of extremes of development of the anal cell in the fore wing. This character is of little significance in the Afrotropical fauna because of its extreme variability. Kivua is provisionally removed to the Allantinae (new placement), because the fore wing anal veins 2A+3A are more or less distinctly indicated. In most other characters, Kivua is closely similar to Neacidiophora Enslin, 1911 (Allantinae), revised by Koch (1998). Eight Kivua species were recognized as valid by Taeger et al. (2010) and eight are added here through recombination, with two species removed to Durbadnus, so that the genus now contains the following 14 species:
Kivua abdominalis Pasteels, 1949
Kivua acuticornis (Pasteels, 1953) comb. n. (Erythraspides acuticornis Pasteels, 1953)
Kivua afra (Pasteels, 1953) comb. n. (Erythraspides afra Pasteels, 1953)
Kivua bicolor (Pasteels, 1949) comb. n. (Bicrista bicolor Pasteels, 1949)
Kivua cara nom. n. (Etymology: from Latin cara (valuable)) for Urocerca luteiventris Pasteels, 1949 (Pasteels 1949a: 67–68). The specific epithet luteiventris is preoccupied in Kivua by K. luteiventris Pasteels, 1949 (Pasteels 1949a: 64–65). No synonym is available for this species, so a new name is required for the secondary homonym, provided that K. cara is considered to belong to the same genus as K. luteiventris.
Kivua cribrifrons (Pasteels, 1949) comb. n. (Urocerca cribrifrons Pasteels, 1949)
Kivua incrassata Pasteels, 1949
Kivua luteiventris Pasteels, 1949
Kivua pallipes (Pasteels, 1949) comb. n. (Urocerca pallipes Pasteels, 1949)
Kivua punctifrons Pasteels, 1949
Kivua seydeli Forsius, 1934
Kivua sudanica (Forsius, 1931)
Kivua tenuis (Pasteels, 1949) comb. n. (Urocerca tenuis Pasteels, 1949).
Kivua violae nom. n. (Etymology: After Viola Richter, assistant in the Hymenoptera Section at the Berlin Museum) for Tumura luteiventris Pasteels, 1949 (Pasteels 1949a: 57–58). The specific epithet luteiventris is preoccupied in Kivua by K. luteiventris Pasteels, 1949 (Pasteels 1949a: 64–65). No synonym is available for this species, so a new name is required for the secondary homonym, provided that K. violae is considered to belong to the same genus as K. luteiventris.
It should also be noted that Neacidiophora quadrifoveata Koch, 1998 is a synonym of Kivua incrassata Pasteels, 1949 (syn. n.), as based on comparison of type specimens. The reason for the misidentification by Koch (1998) is the nearly complete development of 2A+3A in the fore wing of N. quadrifoveata, which is very faintly indicated in most Kivua species, but highly variable. Pasteels (1949b) described intraspecific variability in the anal vein, using Kivua seydeli Forsius, 1934 (the type species of Kivua) as an example. He noted that similar variability occurred in several other Kivua species, including Urocerca.
Five Afrotropical genera are retained in the Blennocampinae. Aethiocampa is characterized by absence of the crossvein Rs+M and a very long, petiolate anal cell (1A) of the hind wing (Fig. 4). The basal lobe of the apically bifid tarsal claws is enlarged (Fig. 5). The head of the only known species in this genus, Aethiocampa aethiopica (Enslin, 1913), especially its frons, is conspicuously transversally microridged and dull. The medial tooth of each mandible is strongly developed (Fig. 25).
Distega is the largest genus of Afrotropical Blennocampinae, with 25 species currently recognized as valid (Taeger et al. 2010). According to Pasteels (1949a), placement of Distega in the Blennocampinae is not necessarily correct, because he sporadically found specimens of different species with variable reduction of the fore wing veins 2A+3A. In fact, apart from a basal stub of 2A+3A (Fig. 1) and in very few cases a very small vestige of these veins at the base of the anal crossvein (Fig. 2; Koch 2000, fig. 34), particularly in D. bevisi, these veins are almost completely obliterated (Fig. 1) in all other species. A distinctive apomorphy of Distega is the continuous suture that divides the upper and lower halves of the mesepisternum (Fig. 24).
Durbadnus, now with three species, is revised below.
Tesslinia is currently considered to be monotypic. The genus possesses a distinctive combination of characters: fore wing vein Rs+M is weakly curved near its junction with R (resembling Selandriinae, but none of these has a basally incomplete fore wing anal cell); the anal cell of the hind wing is very short or nearly impetiolate (Fig. 6); the basal lobe of the apically bifid tarsal claws is flattened (Fig. 7); the medial tooth of the rather slender mandible is very small (Fig. 26); and the head is micropunctate and shiny.
Trisodontophyes is readily separated from other African Blennocampinae by its tridentate claws (Fig. 9). The genus was revised by Koch (2001). Taeger et al. (2010) list 21 extant species as valid.
Checklist of Afrotropical Blennocampinae
Aethiocampa Pasteels, 1949
aethiopica (Enslin, 1913)
Distega Konow, 1904
Paradistega Forsius, 1934
Codistega Pasteels, 1949
Eudistega Pasteels, 1949
Pachydistega Pasteels, 1949
Distegella Pasteels, 1951
abdominalis Forsius, 1931
abyssinica Pasteels, 1955
basilewskyi Pasteels, 1955
bevisi Forsius, 1930
braunsi Enslin, 1911
brunniventris Enslin, 1913
carbonaria Forsius, 1928
clypealis Pasteels, 1955
coeruleomicans Pasteels, 1955
congonensis (Forsius, 1934)
formosa (Pasteels, 1949)
forsiusi Blank, Liston & Taeger, 2009
humeralis Pasteels, 1955
maculata (Forsius, 1934)
micans (Forsius, 1934)
mocsaryi Enslin, 1913
montium Konow, 1907
nigriceps (Enderlein, 1920)
pallidiventris Forsius, 1927
paradoxalis Pasteels, 1954
rectiserra (Pasteels, 1949)
schoutedeni Pasteels, 1954
sjoestedti Konow, 1904
thoracalis (Pasteels, 1949)
velutina (Pasteels, 1951)
Durbadnus Pasteels, 1954
chubbi (Forsius, 1930)
obscuripes (Forsius, 1931)
taegeri sp. n.
Tesslinia Pasteels, 1951
afra (Enslin, 1913)
Trisodontophyes Enslin, 1911
aethiopica Koch, 2001
angustata Enslin, 1913
antennata Koch, 2001
ater (Konow, 1907)
diversa Koch, 2001
funebris Pasteels, 1949
inaequalis Koch, 2001
malaisei (Forsius, 1932)
montana Koch, 2001
nigroflava Enslin, 1911
robertibuyssoni (Schulz, 1906)
robusta Forsius, 1930
schoutedeni Forsius, 1934
semisplendens Koch, 2001
serrula Koch, 2001
singularis Koch, 2001
splendens Koch, 2001
tibialis Enslin, 1913
triplicata Forsius, 1934
tristis Forsius, 1934
ugandae Koch, 2001
Key to genera of Afrotropical Blennocampinae
1 Hind wing with cell M (Fig. 8) or both Rs and M (Fig. 1) present 2
— Hind wing with cells Rs and M absent 3
2 Hind wing only with M (Fig. 8); tarsal claws tridentate, with large basal lobe (Fig. 9); mesepisternum without transverse groove or suture Trisodontophyes
— Hind wing with both Rs and M both (Fig. 1); tarsal claws with one subapical tooth and enlarged basal lobe (Fig. 3); upper half of mesepisternum separated from lower by a transverse groove or suture (Fig. 24) Distega
3 Fore wing with crossvein Rs+M absent, 1R1 and 1Rs are fused, thus there are only two cells (Fig. 4); anal cell of hind wing as long as anal vein 1A (Fig. 4) Aethiocampa
— Fore wing with crossvein Rs+M present, 1R1, 1Rs and 2Rs are present, thus there are three cells (Figs 6, 10, 20); anal cell of hind wing with conspicuously shorter petiole (Figs 6, 10, 20) 4
4 Tarsal claws with conspicuously flattened basal lobe, about half as high as inner subapical tooth (Fig. 7); anal vein 2A of fore wing gradually obliterated apically, so anal cell (2A) open below; anal cell of hind wing very short, nearly impetiolate (Fig. 6) Tesslinia
— Tarsal claws with enlarged basal lobe, nearly equal in height to inner subapical tooth (Fig. 16); anal vein 2A of fore wing completely developed, anal cell closed; anal cell of hind wing petiolate, about equal to width of anal cell (Figs 10, 20) Durbadnus
Genus Durbadnus Pasteels, 1954
Durbadnus: Pasteels 1954: 503. Type species: Monophadnus chubbi Forsius, 1930, by orig. des.
Redescription:
Length 6.0–8.0 mm. Head and abdomen black, thorax black with orange-yellow markings. Antenna filiform, 9-segmented and longer than maximum head width, flagellomere1 conspicuously longer than flagellomere2 or flagellomere3. Head sparsely micropunctate, shiny, without strongly developed structures. Occipital carina absent. Supra-antennal crest moderately developed. Frontal area indistinctly limited. Malar space absent. Clypeus subtruncate, very slightly enlarged medially. Each mandible with strongly developed, double-shouldered, subapical tooth (Fig. 27). Tarsal claws cleft apically, with inner tooth somewhat shorter, and large basal lobe (Fig. 16). Epicnemium absent. In fore wing, M slightly curved and parallel to 1m-cu (Figs 10, 20); cells 1Rs and 2Rs subequal in length (Fig. 20) or 2Rs is as long as 1R1 and 1Rs united (Fig. 10); stub of 2A+3A nearly straight or furcate at apex. Hind wing without closed cells Rs and M, anal cell 2A present and about equal to width of short petiolate anal cell 1A (Figs 10, 20). Tergum1 with more or less wide, deep medial excision.
Remarks: Pasteels (1949a) recognized that M. chubbi Forsius, 1930 is atypical for Monophadnus, because as described by Forsius (1930), the tarsal claws are cleft apically and lobed basally, whilst Monophadnus Hartig, 1837 has simple claws, without basal lobe and subapical tooth. Pasteels (1954) described Durbadnus after he had seen a male of D. chubbi collected by Marley in 1945. However, he perpetuated a mistake made by Forsius (1930): “Hind wings with one closed middle cell”. Actually, in Durbadnus the hind wing does not have a closed middle cell, i.e. cells RS and M are missing.
In the course of this revision, the holotypes of three species described by Forsius (1931) (Blennocampa bensoni, B. obscuripes and B. sudanica) were examined, because they had been described as having a colour pattern similar to Durbadnus. It was found that B. bensoni and B. obscuripes belong to Durbadnus, whereas B. sudanica was confirmed as belonging to Kivua Forsius, 1934, where it was placed by Pasteels (1949a).
Durbadnus species have so far only been found in South Africa, whereas species of the morphologically similar genera Tesslinia Pasteels, 1951 and Aethiocampa Pasteels, 1949 have an Equatorial distribution. The larvae and host plants of Durbadnus are unknown.
Durbadnus chubbi (Forsius, 1930)
Figs 10–15, 28, 29
Monophadnus chubbi: Forsius 1930: 73–75, ♀♂. Type locality: South Africa, KwaZulu-Natal, Durban.
Durbadnus chubbi: Pasteels 1954: 503.
Blennocampa bensoni Forsius, 1931: 27–28, ♀♂. Type locality: South Africa, Eastern Cape, Port St Johns. Syn. n.
Kivua bensoni: Pasteels 1949a: 60.
Redescription:
Female.
Head black; labrum light brown, apical half of mandible reddish brown. Thorax black; pronotum, tegula, lateral lobes of mesoscutum except for a large black medial spot, lateral margin of medial lobe of mesoscutum, postspiracular sclerite, dorsal half of mesopleuron, and anepimeron orange. Legs blackish; tibiae and tarsi whitish, only at extreme apices of tibiae and tarsomeres5 somewhat darker. Wings subhyaline; costa, subcosta and base of venation blackish, stigma and rest of venation light brown. Abdomen black.
Head narrowed behind eyes. (Antenna as long as head and thorax together; vide Forsius 1931 for Blennocampa bensoni. Flagella of Monophadnus chubbi holotype missing; vide Forsius 1930.) POL:OOL = 1.0:0.8. Postocellar area: width: length = 1.0:0.7, lateral furrows slightly divergent posteriorly and convex; a longitudinal medial furrow shallowly developed, especially at the anterior margin. Supra-antennal grooves large and deep, no furrow developed towards torulus. Interantennal area with very small medial groove. Eyes converge downwards, lower interocular distance as long as eye length. Supraclypeal furrow deep.
Head more or less micropunctate, shiny; pubescence on head pale, somewhat shorter than the diameter of lateral ocellus. Thorax sparsely micropunctate, shiny; pubescence pale, shorter than that on head. In fore wing, cell 2Rs as long as 1R1 and 1Rs united; stub of 2A+3A more or less straight at apex (Fig. 10).
Tergum1 with moderately wide but deep medial excision. Terga transversally microridged, dull. Sawsheath in lateral view pointed at apex (Fig. 11), in dorsal view very narrow towards apex.
Lancet as in Fig. 12, with scattered, conspicuous longer setae at centre towards base; with approx. 27 serrulae; serrulae at centre very flat, truncate apically, with about 8–11 very small posterior denticles and 3 anterior denticles (Fig. 13).
Length 6.7–7.3 mm.
Male.
Colouration similar to that of female. Mesoscutum completely black, only lateral margin of lateral lobe orange. Fore femur dirty white, mid and hind femora dirty white at apices.
Head conspicuously narrowed behind eyes. Antenna 1.3 times as long as maximum width of head; flagellomere1 0.9 times as long as flagellomeres2/3 combined. POL:OOL = 1.0:0.6–0.8. Other features as for female. Penis valve as in Fig. 14; parapenis and harpe as in Fig. 15.
Length 5.3–6.0 mm.
Type material examined:
Monophadnus chubbi. Holotype (Figs 28, 29): ♀: “Holotype” [red]; “Durban [29°51′S 31°01′E], Natal, 18.X.1920, C. N. Barker, 2578”; “Monophadnus chubbi n. sp. ♀, Holotype, R. Forsius det.”; “Holotype, Monophadnus chubbi Forsius ♀, teste: F. Koch, 2011” [red]; “Durbadnus chubbi (Forsius) ♀, det: F. Koch, 2011” (DMSA). Condition: Antennae missing except for left antennomeres1+2; legs and wings partly damaged. Paratype: 1♂ same data as holotype (DMSA).
Blennocampa bensoni. Holotype: ♀ “Type, H. T.” [red circle]; “S. Africa, R. E. Turner, Brit. Mus., 1923-510”; “Port St. Johns [31°38′S 29°32′E], Pondoland [= Eastern Cape], IX.1923”; “B. M. Type, Hym., 1.379”; “Blennocampa bensoni n. sp. ♀, holotypus, R. Forsius”; “Holotypus, Blennocampa bensoni Forsius ♀, teste: F. Koch, 2011” [red]; “Durbadnus bensoni (Forsius) ♀, det.: F. Koch, 2011” (BMNH). Condition: Flagella and left rear tarsus missing. Paratype: SOUTH AFRICA: KwaZulu-Natal: 1♂ Eshowe [28°53′S 31°28′E], 1–22.iv.1926 (UZMT). Condition: Thorax ventrally damaged by pin; two left apical flagellomeres missing.
Other material examined: SOUTH AFRICA: KwaZulu-Natal: 1♂ Umbilo [29°52′00″S 30°58′42″E], 14.X.1945, Marley (DMSA).
Distribution: South Africa (Fig. 34).
Remarks: The type material of M. chubbi was examined and compared with that of B. bensoni. It was not possible to find any significant differences between these specimens, and therefore they are considered to be conspecific.
Variability in D. chubbi occurs in the shape of the medial furrow of the postocellar area. This is distinctly developed in the female holotype of M. chubbi, weaker in the female holotype of B. bensoni, and absent in all males examined.
Durbadnus chubbi differs from other Durbadnus species in the large cell 2Rs of the fore wing, which is as long as cells 1R1 and 1Rs united (Fig. 10). In D. taegeri (Fig. 20) and D. obscuripes, 1Rs and 2Rs are about equal in their lower length; in D. chubbi, 1R1 is conspicuously shorter. Additionally, in the fore wing, the stub of 2A+3A of D. chubbi is more or less straight at the apex, whereas in D. taegeri and D. obscuripes it is apically furcate (Fig. 20).
Durbadnus obscuripes (Forsius, 1931), comb. n.
Figs 16–19, 30, 31
Blennocampa obscuripes: Forsius 1931: 28–30, ♀. Type locality: South Africa, Eastern Cape, Umtata. Kivua obscuripes: Pasteels 1949a: 60.
Redescription:
Female.
Head black; apical half of mandible reddish brown. Thorax black; pronotum, tegula, lateral lobes of mesoscutum except for a large black medial spot, medial lobe of mesoscutum at extreme angle, and postspiracular sclerite orange. Legs black; apical half of fore femur and fore tibia yellow. Wings uniformly slightly infuscate; stigma, costa, subcosta, and rest of venation blackish. Abdomen black.
Head very slightly narrowed behind eyes. Antenna 1.3 times as long as maximum head width; flagellomere1 0.7 times as long as flagellomeres2/3 combined. POL:OOL = 1.0:0.7. Postocellar area: width:length = 1.0:0.5–0.6 (0.6 HT), lateral furrows convex. Supraantennal grooves large and deep, with conspicuous furrow towards lateral margin of torulus. Interantennal area with shallow, transverse oval groove and two small lateral grooves, longitudinal furrow interrupts front margin of frontal area medially and ends at front ocellus. Eyes converge downwards, lower interocular distance 1.1 times as long as eye length. Supraclypeal furrow deep.
Head very sparsely micropunctate, shiny; pubescence on head brown, somewhat shorter than diameter of lateral ocellus. Thorax nearly impunctate, shiny; pubescence yellow, shorter than that on head. In fore wing, cells 1Rs and 2Rs subequal in length; stub of 2A+3A furcate (Fig. 20).
Tergum1 with wide and deep medial excision. Terga1/2 smooth and shiny, following terga sparsely micropunctate, shiny. Sawsheath in lateral view roundly pointed at apex (Fig. 17), in dorsal view very narrow towards apex.
Lancet (Fig. 18) has very long setae, especially at basal half; with approx. 18–19 serrulae; serrulae at centre flatly prominent, with about 7 or 8 irregular posterior denticles and 4 or 5 irregular anterior denticles (Fig. 19).
Length 6.7–8.0 mm.
Male. Unknown.
Holotype (examined): ♀ “Type, H. T.” [red circle]; “S.Africa, R. E.Turner, Brit. Mus., 1923-189”; “Umtata [31°35′S 28°47′E], Transkei [= Eastern Cape], 18.II–923”; “B. M. Type, Hym., 1.378”; “Blennocampa obscuripes n. sp. ♀, R. Forsius”; “Holotypus, Blennocampa obscuripes Forsius ♀, teste: F. Koch, 2011” [red]; “Durbadnus obscuripes (Forsius) ♀, det: F. Koch, 2011” (BMNH). Condition: Right fore wing damaged.
Paratype (examined): 1♀ same data as holotype (UZMT). Condition: Fair.
Distribution: South Africa (Fig. 34).
Remarks. The colour pattern of D. obscuripes is very similar to that of D. taegeri. However, the latter species differs in having yellowish fore tibiae and because of the smaller black medial spot on the lateral lobes of mesoscutum. In D. taegeri, flagellomere1 is as long as flagellomeres2/3 combined, whereas in D. obscuripes, flagellomere1 is conspicuously shorter. In particular, D. obscuripes is distinguished by the shape of serrulae, which are flatter than in D. taegeri. Furthermore, the lancet of D. obscuripes, especially at its base, bears very large sensilla. In the paratype, these sensilla are also present, but somewhat fewer in number. It is possible that they break off during oviposition.
Durbadnus taegeri sp. n.
Figs 20–23, 27, 32, 33
Etymology: The new species is named after our colleague and specialist on Symphyta, Dr Andreas Taeger, curator of Hymenoptera and Lepidoptera at the Senckenberg Deutsches Entomologisches Institut, Müncheberg.
Description:
Female.
Head black; apical half of mandible reddish brown. Thorax black; pronotum, tegula, lateral half of lateral lobe of mesoscutum, medial lobe of mesoscutum at extreme angle, and postspiracular sclerite orange-yellow. Legs black; anterior surface of apical half and apex of posterior surface of fore femur yellow, fore tibia and fore basitarsomere at base dirty whitish. Wings uniformly slightly infuscate; stigma, costa, subcosta and rest of venation blackish. Abdomen black.
Head very slightly narrowed behind eyes. Antenna 1.4 times as long as maximum head width; flagellomere1 as long as flagellomeres2/3 combined. POL:OOL = 1.0:0.7. Postocellar area: width:length = 1.0:0.7, lateral furrows slightly convex. Supra-antennal grooves large and deep, with conspicuous furrow at lateral margin of torulus. Inter-antennal area with rounded groove and small longitudinal furrow medially, ending at front margin of frontal area. Eyes converge downwards, lower interocular distance 1.1 times the length of the eye. Supraclypeal furrow deep.
Head sparsely micropunctate, shiny; pubescence on head brown, longer than diameter of lateral ocellus. Thorax more densely punctate, shiny; pubescence yellow, shorter than that on head. In fore wing, cells 1Rs and 2Rs subequal in length; stub of 2A+3A furcate (Fig. 20).
Tergum1 with wide and deep medial excision. Terga1/2 smooth and shiny, following terga transversally microridged and micropunctate, shiny. Sawsheath in lateral view narrowly rounded at apex (Fig. 21), in dorsal view narrowed toward apex.
Lancet as in Fig. 22, having about 23 serrulae; serrulae at centre moderately prominent, with about 4 or 5 irregular posterior denticles and 3 or 4 irregular anterior denticles (Fig. 23).
Length 6.7 mm.
Male. Unknown.
Holotype: ♀ “Republic of South Africa: Cape Prov. [Western Cape], Citrusdal, 1 km N Hexrevier [Heksrivier, 32°26′00″S 18°57′40″E], 6.X.1994, shrubs at riverside, M. Söderlund”; “Holotypus, Durbadnus taegeri ♀ sp. n., det.: F. Koch, 2011” [red] (USNM). Condition: Good.
Distribution: South Africa (Fig. 34).
Remark: Durbadnus taegeri is the first recorded member of the Tenthredinidae in the winter-rainfall zone of western South Africa.
Key to species of Durbadnus
1 Cell 2Rs in fore wing as long as cells 1R1 and 1Rs united (Fig. 10); stub of veins 2A+3A nearly straight chubbi
— Cells 2Rs and 1Rs subequal in length (Fig. 20); stub of 2A+3A furcate apically 2
2 Flagellomere1 conspicuously shorter than flagellomeres2+3 combined. Only small black spot on inner lateral lobe of mesonotum. Serrulae of lancet flatter (Figs 18, 19) obscuripes
— Flagellomere1 as long as flagellomeres2+3 combined. Approximately half of inner lateral lobe of mesonotum black. Serrulae of lancet higher (Figs 22, 23) taegeri sp. n.
ACKNOWLEDGEMENTS
We thank the following persons who made material in their collections available to us for study: G. Lungi (DMSA); S. Ryder (BMNH); D.R. Smith (USNM); and J. Vauras and A. Teräs (UZMT). D.R. Smith also made valuable improvements to the manuscript. Many thanks go to G. Goergen for providing the photograph of Durbadnus taegeri in dorsal view. Finally, the International Bureau of the Federal Ministry of Education and Research (BMBF) at the Project Management Agency c/o the German Aerospace Center (DLR) (SUA 08/058) and the National Research Foundation, South Africa, are gratefully acknowledged for providing a research grant to the senior author.